Gottfried Wilhelm Leibniz,

the humanist agenda and

the scientific method

Kundan Misra

This book is based on a thesis by Kundan Misra which satisfied the requirements for the

degree of Master of Science (Research), University of New South Wales.

The project was conducted under the supervision of Professor James Franklin. The research

started in 2008, the thesis was submitted for examination in August 2011, changes requested

by examiners were completed in September 2012, and in the same month the university

decided to award the degree.

© Copyright 2012

Licenced under the Creative Commons Attribution Licence

For licence details, see www.creativecommons.org.au

The author may be contacted at kundan at austi dot org or kundanmisra at yahoo dot com

Abstract

Modernity began in Leibniz’s lifetime, arguably, and due to the efforts of a group of

philosopher-scientists of which Leibniz was one of the most significant active contributors.

Leibniz invented machines and developed the calculus. He was a force for peace, and

industrial and cultural development through his work as a diplomat and correspondence with

leaders across Europe, and in Russia and China. With Leibniz, science became a means for

improving human living conditions. For Leibniz, science must begin with the “God’s eye

view” and begin with an understanding of how the Creator would have designed the universe.

Accordingly, Leibniz advocated the a priori method of scientific discovery, including the use

of intellectual constructions or artifices. He defended the usefulness and success of these

methods against detractors. While cognizant of Baconian empiricism, Leibniz found that an

unbalanced emphasis on experiment left the investigator short of conclusions on efficient

causes. Leibniz worked outside, but complemented, the current of formal reasoning and

empiricism which was developing in scientific circles during his lifetime. He supported the

development of methods for calculation and demanded precise reasoning, while arguing that it

was folly to omit the Neoplatonic orientation from science. Indeed, without Neoplatonism

there would be no modernity. Leibniz’s Neoplatonic course complemented his work with

machines. Leibniz crystallised the Neoplatonic orientation as a pragmatic humanist agenda,

and merged it with national imperatives for developing science. Leibniz’s policy orientation is

aligned with the Hermetic conception of Man as magus, who ultimately can control even the

stars. The industrial-scientific age which followed Leibniz is a testament to the success of his

life’s work.

Acknowledgements

I first met Professor James Franklin in 2007 to discuss the possibility of a project that

investigates the metaphysical and philosophical assumptions of Leibniz in his mathematical

work, most notably the calculus. I did not realise how arduous the journey was going to be, or

where in history it was going to take me. Professor Franklin provided intellectual support,

guidance and critical suggestions to keep the project going and to keep me focussed on the

original aim. The project would have reeled off the rails without Professor Franklin’s vast

knowledge of mathematics, the history of science and philosophy. The research touched many

areas and Professor Franklin always ensured that I avoided spending too much time on

backstreets and in blind alleys while allowing new ideas to be picked up in those segues.

There were many segues!

Thank you Professor Franklin for supporting me in this odyssey. Some segues became major

new paths. Thank you for your sensitivity in striking the delicate balance between allowing

new ideas to germinate while ensuring existing ideas were developed to maturity. Thank you

for your encouragement and wisdom in confronting and overcoming the many intellectual and

research obstacles.

I appreciate the recommendations of Postgraduate Review Committee in each annual review

which helped greatly in making the following year fruitful.

The thesis examiners clearly spent many hours poring over the thesis and in writing frank and

constructive comments. The examiners’ feedback exposed and proposed many ways to

improve the thesis, which I have acted upon. For example, greater depth of research into the

origins of Neoplatonism and the relevance of Hermetism was encouraged. The result was a

new chapter which is now Chapter 2 along with improvements throughout the thesis.

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Contents

Preface ....................................................................................................................................... 9

Abbreviations .......................................................................................................................... 11

Terminology ............................................................................................................................ 14

Chapter 1: Introduction......................................................................................................... 23

Chapter 2: Neoplatonism and the awakening of science .................................................... 26

Chapter 3: Ushering in modernity ........................................................................................ 42

Chapter 4: Idea of truth......................................................................................................... 72

Chapter 5: The Neoplatonist and Empiricist schools ......................................................... 82

Chapter 6: Discovery and deduction .................................................................................. 109

Chapter 7: Science by thought, and reality and substance .............................................. 124

Chapter 8: The ongoing role of thought and the ongoing creation of the Best .............. 148

Chapter 9: A priorism in science ......................................................................................... 178

Chapter 10: Conclusion – Leibniz’s humanist and Neoplatonic agenda ........................ 192

Appendix 1: To the greater glory of God ........................................................................... 198

Appendix 2: A proof from basics ........................................................................................ 202

Bibliography ......................................................................................................................... 204

Page 2

Page 3

Detailed contents

Contents ..................................................................................................................................... 1

Detailed contents ...................................................................................................................... 3

Preface ....................................................................................................................................... 9

Abbreviations .......................................................................................................................... 11

Terminology ............................................................................................................................ 14

Chapter 1: Introduction......................................................................................................... 23

Chapter 2: Neoplatonism and the awakening of science .................................................... 26

Introduction .......................................................................................................................... 26

The first Neoplatonists were “new Platonists” ..................................................................... 26

Arab philosophers ................................................................................................................ 27

Hermeticum and magic in Europe ........................................................................................ 30

Giordano Bruno ................................................................................................................ 31

Hermes in Europe by mistake .......................................................................................... 32

Natural magic ................................................................................................................... 33

The other kind of Neoplatonism, and operations ................................................................. 34

The Greeks as operators ....................................................................................................... 36

Mathematics in operations ................................................................................................... 37

Symbols ................................................................................................................................ 39

Conclusion ............................................................................................................................ 41

Chapter 3: Ushering in modernity ........................................................................................ 42

Introduction .......................................................................................................................... 42

Leibniz’s relationship to modernity ..................................................................................... 44

Laws that function without divine intervention ................................................................... 44

Hylarchic principle ............................................................................................................... 45

Modernity and discoveries achieved by reason .................................................................... 46

Hypothesizing a priori ......................................................................................................... 47

Broad-based influence of reason on culture ......................................................................... 49

Conflicting ideas on the nature of Reason ........................................................................... 50

Nicolaus of Cusa .................................................................................................................. 51

Cusa’s ideas on mind gain traction in science ...................................................................... 54

Vis viva or effect-producing force ........................................................................................ 56

Machines are indispensable to the concept of modernity .................................................... 58

Political influences on and of Leibniz .................................................................................. 61

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Seeking to understand Creation as a whole .......................................................................... 63

Geometry as a tool to understand Creation as a whole ........................................................ 65

Understanding Creation as a whole, and improving upon it ................................................ 66

Philosopher scientists and French nation-building ............................................................... 67

An era of pro-nuclear advocacy ........................................................................................... 70

Participating with God in Creation ....................................................................................... 71

Chapter 4: Idea of truth......................................................................................................... 72

Introduction .......................................................................................................................... 72

Minds can successfully search for truth ............................................................................... 72

Sense perception and Empiricism ........................................................................................ 74

Existence and attainability of truth: Rationalism and Neoplatonism, vs Empiricism .......... 76

Religious or moral truth vs scientific truth ........................................................................... 78

Neoplatonism, Empiricism and Atheism ............................................................................. 79

Summary of the ’isms .......................................................................................................... 80

Conclusion ............................................................................................................................ 80

Chapter 5: The Neoplatonist and Empiricist schools ......................................................... 82

Introduction .......................................................................................................................... 82

Schiller and the infinite ........................................................................................................ 84

Metaphysical calculations and a method of Analysis for concepts in physics ..................... 85

Invaluable medieval speculations ......................................................................................... 86

Leibniz saw the need for more powerful methods ............................................................... 86

Reason gives value to observations ...................................................................................... 87

Kepler, Neoplatonism and precision .................................................................................... 89

The Empiricist school and the influence of Paolo Sarpi ...................................................... 91

Sarpi and Galileo .................................................................................................................. 91

Sarpi’s influence in England ................................................................................................ 92

Sarpi’s closeness to Galileo .................................................................................................. 93

Sarpi and atheism ................................................................................................................. 94

Sarpi and Newton ................................................................................................................. 95

From Galileo to Newton ....................................................................................................... 95

Leibniz comments on the experimental program of the (British) Royal Society ................. 96

Newton’s prescribed method of discovery ........................................................................... 96

Evolution of Newton’s method of discovery ....................................................................... 98

Newton against hypothesis and towards mathematicization ................................................ 99

Knowledge without sensation .............................................................................................. 99

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Kepler and Leibniz in Newton’s method ........................................................................... 101

Consequences of mandating empirico-logic ...................................................................... 102

Empirico-logic in other domains ........................................................................................ 104

Reasoning other than empirico-logical .............................................................................. 105

The role of rigorists ............................................................................................................ 106

Conclusion .......................................................................................................................... 107

Chapter 6: Discovery and deduction .................................................................................. 109

Introduction ........................................................................................................................ 109

The art of discovery ............................................................................................................ 110

Discovery is often metaphysics .......................................................................................... 112

Un-rigorous use of rigor ..................................................................................................... 113

Archimedes had the same problem .................................................................................... 114

All things and no things – at the same time ....................................................................... 115

Does the infinite exist? It doesn’t really matter. ................................................................ 116

Do Platonic ideas exist? It doesn’t really matter. ............................................................... 118

Rigor is of service .............................................................................................................. 120

Science may use indemonstrables ...................................................................................... 120

Global architecture determines local mechanics ................................................................ 121

Intention in the large .......................................................................................................... 122

Conclusion .......................................................................................................................... 123

Chapter 7: Science by thought, and reality and substance .............................................. 124

Introduction ........................................................................................................................ 124

Science by thought ............................................................................................................. 125

Universal characteristic ...................................................................................................... 125

Dream vs reality, and substance vs phenomena ................................................................. 126

What is real? ....................................................................................................................... 127

Monads are real .................................................................................................................. 127

Immaterial souls exist ......................................................................................................... 129

The nature of ideas ............................................................................................................. 129

The applicability of ideas ................................................................................................... 131

Ideas and “the Best” are outside all that exists ................................................................... 133

The apparent governance over actual things by ideas ........................................................ 133

The relationship between ideas and actual things .............................................................. 134

Inexorable necessity created by the requirement of “the Best” ......................................... 135

Nominalism ........................................................................................................................ 136

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Interdependence of ideas .................................................................................................... 137

Simple monads and compound monads ............................................................................. 138

Passive vs active, or body vs soul ...................................................................................... 141

Actions of monads .............................................................................................................. 142

Immaterial realm is in harmony with material realm ......................................................... 143

Life ..................................................................................................................................... 143

Q&A ................................................................................................................................... 143

The Hermetic monad .......................................................................................................... 144

What survives death? ......................................................................................................... 145

Human souls differ from souls of beasts ............................................................................ 145

Monads are the same as one another .................................................................................. 146

Conclusion .......................................................................................................................... 147

Chapter 8: The ongoing role of thought and the ongoing creation of the Best .............. 148

Introduction ........................................................................................................................ 148

Choices God makes, continuously ..................................................................................... 148

First kind of choice: God mediates between monads ..................................................... 149

Second kind of choice: God chooses the best possible from what is possible ............... 150

Unanswered question re first kind of choice .................................................................. 151

Consideration re first kind of choice: God’s choices vs intelligent monads’ choices .... 151

Question re second kind of choice ................................................................................. 152

Answer to the question re second kind of choice: what God does from moment-to-

moment ........................................................................................................................... 152

Creating the universe anew in each moment ...................................................................... 153

Is it “Hello Humphrey Appleby” or, Does God control everything while appearing not to?

............................................................................................................................................ 154

Mystical theology ............................................................................................................... 155

Mathematical determinism ................................................................................................. 158

Is everything planned in advance? ..................................................................................... 159

A priorism ........................................................................................................................... 160

Is a priorism better than empirics? ..................................................................................... 160

For humans, ideas and empirics are interdependent .......................................................... 161

Free will .............................................................................................................................. 162

What is an evil person? ...................................................................................................... 163

The problem of evil ............................................................................................................ 164

Scientific comprehensibility of God’s plan ........................................................................ 166

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Intention and the Scholastic Leibniz project ...................................................................... 167

God’s thoughts are made real by his will ........................................................................... 171

Thoughts that soul monads have ........................................................................................ 172

Humankind as a subject of physical science ...................................................................... 173

“Ideas” (in the strict monadological sense) about humankind ........................................... 174

Foundations of a programme for discovery ....................................................................... 175

Conclusion .......................................................................................................................... 176

Chapter 9: A priorism in science ......................................................................................... 178

Introduction ........................................................................................................................ 178

Example 1: The infinitesimal and the calculus .................................................................. 180

Arithmetical progression ................................................................................................ 183

Eliminating terms ........................................................................................................... 183

Moments ......................................................................................................................... 183

Example 2: The Fifth Postulate and Non-Euclidean geometry .......................................... 184

Example 3: Elliptical orbits in a heliocentric solar system ................................................ 188

Alternative views of the Creator’s mind ............................................................................ 190

Conclusion .......................................................................................................................... 191

Chapter 10: Conclusion – Leibniz’s humanist and Neoplatonic agenda ........................ 192

Introduction ........................................................................................................................ 192

Leibniz and humanism ....................................................................................................... 192

Human progress .................................................................................................................. 192

Broadening the field of debate for Platonism ..................................................................... 193

Considering the big questions first ..................................................................................... 193

Human capability ............................................................................................................... 193

Human knowledge .............................................................................................................. 194

A new metaphysics as a blueprint for the good in human society ..................................... 195

Flexibility in scientific method, and the ultimate journey ................................................. 195

Leibniz’s policy for nations ................................................................................................ 197

Appendix 1: To the greater glory of God ........................................................................... 198

Appendix 2: A proof from basics ........................................................................................ 202

Bibliography ......................................................................................................................... 204

Page 8

Page 9

Preface

This publication is based on my MSc (Research) thesis awarded by the University of New

South Wales through the School of Mathematics and Statistics in 2012, supervised by

Professor Jim Franklin. There are minor changes from the original thesis, mostly in the last

page and section of the Conclusion.

The project began with the question of how Leibniz’s metaphysics influenced his

mathematical work. We found that Leibniz was just one of a number of thinkers who did

science by beginning with plausible and quasi-theological first principles regarding creation

as a whole. Scientific questions then act as pieces in a jigsaw puzzle in a quest for

understanding creation as a whole and the role of humanity in it. Mathematics is one tool

available to humans not merely to carry out calculations but to seek truth. Leibniz was one of

a line of thinkers who proceeded in this way. Significant forebears of Leibniz include

Nicolaus of Cusa and Johannes Kepler.

This orientation did not arise spontaneously but has ancient roots. In particular, there are

many parallels between Leibniz’s philosophy and the Hermetic corpus. Through the analysis

of Frances Yates, it is understood that the putative writings of Hermes Trismegistus were

central to the Neoplatonic revival and associated Humanist Renaissance. It seems that Leibniz

developed and systematised proto-science of figures such as John Dee, referred to by

Cornelius Agrippa as “real artificial magic”. The origin and potential of such so-called

“magic” which included proto-science and early engineering was appreciated by Giordano

Bruno and the circles he influenced. Further understanding the debt that Leibnizian thought

owes to Bruno and Egyptian “magic” is a promising direction for further work.

During the research, the dichotomy between thought and sense perception arose many times.

Of course, this has been discussed since Hermes and was addressed in detail in Plato’s The

Republic and by nearly every philosopher in Classical Athens and since. Generally speaking,

the Platonists are oriented towards a priori discovery – using the mind to construct

hypotheses – whose outcomes can be tested in controlled experiment. In the construction of

hypotheses, mathematical preconceptions of the universe play a central role because they

imply structure which becomes the foundation of predictive hypotheses which can be tested.

General sense perception is distrusted as not just unreliable but misleading. As an inventor

and pragmatist himself, Leibniz saw the necessity for experiment and described how he would

catalogue all desired experiments when trying to understand a particular issue in physics. The

distinction is that Leibniz did not expect answers to come from experiment. Rather,

experiments were merely an aid to the a priori thought process.

We found exciting open questions which if addressed would present the opportunity for leaps

in science. One example is a serious conception of “the Best” in the context of Leibniz’s best

of all possible universes doctrine. Another example is further detail on the pre-established

harmony, wherein God intervenes from moment-to-moment to ensure the best possible

correspondence between the thoughts of incorporeal substance (“mind”) and phenomena

exhibited by corporeal substance (“body”). Another is the question of Man as a physical

scientific force in the universe. Another is that which has received much attention but little

progress since Leibniz himself, which is the formulation of a Universal Characteristic, or

symbolic calculus whereby all kinds of problem can be solved in a systematic way.

Page 10

Page 11

Abbreviations

Copenhaver: Copenhaver, B.P. Hermetica Cambridge University Press 1992

Klemm: Klemm, F. (Singer, D. W. trans.) A History of Western Technology Allen and Unwin,

London 1959

Loemker: Loemker, L. E. Gottfried Wilhelm Leibniz: Philosophical Papers and Letters 2nd

ed. D. Reidel, Dordrecht Holland 1969

Monadology: Latta, R. (trans.), Leibniz, G.W. Monadology Oxford University Press 1898

edition

Theodicy: Huggard, E.M. (trans.), Leibniz, G.W. Theodicy §Project Gutenberg edition 2005

accessed at www.gutenberg.com

Wiener: Wiener, P.P. (ed.) G. W. Leibniz Selections New York: C. Scribner, 1951

Wootton, D. Paolo Sarpi: Between Renaissance and Enlightenment Cambridge University

Press, 2002

Yates 1964: Yates, F. Giordano Bruno and the Hermetic Tradition Routledge and Kegan Paul

Ltd London 1964

Yates 2009: Yates, F. Giordano Bruno and the Hermetic Tradition Routledge Classics, digital

reprint 2009

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Page 13

In fact, … final causes may be introduced with great

fruitfulness even into the special problems of physics,

not merely to increase our admiration for the most

beautiful works of the supreme Author, but also to help

make predictions by means of them which would not be

as apparent, except perhaps hypothetically, through the

use of efficient causes. Philosophers have in the past

perhaps not sufficiently observed this advantage of

final causes.

It must be maintained in general that all existent facts

can be explained in two ways – through a kingdom of

power or efficient causes and through a kingdom of

wisdom or final causes; that God regulates bodies as

machines in an architectural manner according to laws

of magnitude or of mathematics but does so for the

benefit of souls and that he rules over souls, on the

other hand, which are capable of wisdom, as over

citizens and members of the same society with himself,

in the manner of a prince or indeed of a father, ruling to

his own glory according to the laws of goodness or of

morality. Thus, these two kingdoms everywhere

permeate each other, yet their laws are never confused

and never disturbed, so that the maximum in the

kingdom of power, and the best in the kingdom of

wisdom, take place together.1

G. W. Leibniz, Specimen Dynamicum 1695

1 Loemker, p.442. Liberty has been taken to break the passage into two paragraphs.

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Terminology

We introduce some terminology and distinctions that are peculiar to the philosophy of

science, and which we use throughout the thesis. In the following list of terms, we group

associated terms rather than following a strict alphabetical order.

In the thesis, we will capitalise terms relating to new concepts introduced by Leibniz and

others which have not yet developed into methods in general use. Examples are Analysis as

Leibniz uses the term, versus the more general “analysis” in day-to-day usage. Another

example is Metaphysics as Leibniz understands it, versus mathematics which Leibniz

generally used in the same sense as everyone else. Another example is “the Best” where best

refers to the actuality of structures in the universe as designed by God as “the best possible

universe”. In any case, we hope that the reader does not set too much store by capitalisation.

A posteriori One is said to formulate a hypothesis or to gain understanding a posteriori if

one does so after and pursuant to or as a result of actual experience or

observation of physical events or empirical evidence.

A priori One is said to understand something a priori or prior to experience by working

it out in one’s mind.

Architectonic Leibniz’s adjective for the planned architecture and creation of the universe

and the laws by which it operates.

Averroes A Muslim thinker credited or discredited with extending Aristotle’s ideas into

positivism. St Thomas Aquinas who was active approximately a century later

was an ardent critic, and wrote that Averroes and extended Aristotle’s ideas far

beyond what Aristotle intended.

Averroism The doctrine that formal deduction is the only valid way to reason. It is named

after its leading proponent Averroes, a Muslim thinker, who adopted Aristotle’s

idea and extended them. Thomas Aquinas disagreed with Averroes’ reading of

Aristotle claiming that Averroes had commandeered Aristotle to support his

own agenda or outlook on the art of thought whether philosophical, scientific,

artistic, etc. Averroist reasoning or logic became increasingly influential. By

the 17th Century the University of Padua, formerly humanist, became a centre

for teaching and promoting Averroes’ method. Averroism was an attempt to

interpret Aristotelian teachings without concern for consistency with Christian

theology. The Latin Averroists at the University of Paris “seemed, at least to

their critics, to abandon the Scholastic attempt to reconcile the newly translated

texts of Aristotle with the dictates of Christian orthodoxy.”2

Baconian The doctrine that experimental effort to discover, record and categorise the

testimony of the senses is the way that science should be done. Early figures in

2 Petrarca relates in an entertaining way how his differences with an Averroist who came to visit him, with

emphasis on the gratuitous disrespect shown by the visitor to the Scriptures and Apostles. Petrarca “An

Averroist visits Petrarca” From a letter to Boccaccio from Venice 28 August 1364, pp.140-141 in Cassirer, E.,

Kristeller, P. O., Randall, J. H. Jr (eds and trans.) The Renaissance Philosophy of Man Phoenix Books,

University of Chicago Press 1948

Page 15

English scientific circles prior to the Royal Society, especially Francis Bacon,

promoted this outlook.

Empiricism The doctrine that what is knowable, and even what is worthy of consideration,

includes only what is perceptible. Galileo was perhaps the fork in the road, for

he had great success in science, especially mechanics, and apparently through

the extensive use of experiment. Galileo was both Kepler’s friend and,

financially, was supported by Paolo Sarpi who was supposedly the first to look

through Galileo’s telescope. Sarpi was an influential gentleman, politician and

statesman and wrote a rudimentary version of what later appeared as the rules

of Newtonian science. Arguably, it was in Galileo and Sarpi that the

empiricism of Newtonian science first took form. Today empiricism is

associated with Francis Bacon with whom Sarpi corresponded, and with Isaac

Newton and John Locke who were born after the deaths of Bacon and Sarpi.

Empiricism was pronounced in English scientific circles and is often associated

with Bacon, Isaac Newton and John Locke. The Royal Society of London for

Improving Natural Knowledge (“Royal Society”) was founded in 1660 out of

English scientific circles and, accordingly, empiricism is dominant in the

orientation of Royal Society. There are also strains in 17th Century English

science which are almost anti-empiricist. Henry More and Robert Boyle are

notable examples who will be discussed in this thesis.

Empiricist A scientist or philosopher thinker who believes in a more a posteriori approach

to science.

Conception, concept or notion (Leibniz’s usage) The content of a thought abstracted from

the thought, or the meaning of a thought in terms mathematical, symbolic,

logical or otherwise regarded with coherent and rational structure as far as

possible. Nearly all human thoughts are inexact, indistinct, confused or

defective in some way. Some thoughts are clearer, more coherent and less

confused than others.

Idea (Leibniz’s usage) A concept that is clear, distinct, self-consistent and consistent

with every other idea. Ideas do not exist independently of minds, but only exist

in minds, whether those of souls or of God. For Leibniz, ideas are not

subjective, are not social constructs and are not constructed but only

discovered. For Leibniz, ideas are concepts which are coherent. The ultimate

test of coherence is God’s design of the best possible universe which is the

actual universe that we are living in. Thus, an idea has explanatory capability.

Ideal A perfect or pure version of a thing or concept, including mathematical

concepts and geometrical constructions.

Perception (Leibniz’s usage) A thought or the way in which something is understood

by a mind. This is contrary to the standard use of the word to refer to

perceiving through the bodily senses.

Thought (noun, Leibniz’s usage) Used interchangeably with “perception”. It is a thought

is a mental image or, more generally, a mental impression.

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Rational thought (verb) The wilful process of creating mental impressions, and of

bringing structure to concepts. It might also be called “intellection” or “creative

mentation”. This is the process through which hypotheses are made, which are

often tantamount to discoveries though to earn the label “discovery”

confirmation via experiment or mathematical deduction or both is usually

needed. For Leibniz, holding all concept and information related to a problem

or circumstance in one’s mind in a single thought was a prerequisite to the

understanding which precedes a new subsuming higher hypothesis. For Kepler,

it was seeking after the manifestation of harmony in the context being analysed

that provided the superior or most fruitful impetus towards the higher

hypothesis. Each is an example of an a priori process.

Metaphysics The study of the relations, constraints and principles that underlie the physical

universe and that underlie physics. Metaphysics may also refer to philosophical

rules that govern one’s assumptions in and approach to physical science. The

Stanford Encyclopedia of Philosophy says that the term derives from Aristotle’s

Metaphysics.3 Whether or not this is true, Aristotle was not the first to deal with

metaphysics nor did subsequent thinkers, such as Leibniz, agree with

Aristotle’s Metaphysics on all points or even on fundamental points. The

Stanford Encyclopedia of Philosophy says that metaphysics is about things that

do not change, in contradistinction to physics which is about the physical world

which does change. However, it is not at all certain that metaphysics is not

dynamic or not evolving. In order to make progress in metaphysics, it is

generally necessary to step outside of any confinement by assumptions derived

from the physical universe. This may lead to considerations concerning the

origin of the physical universe which quickly leads to questions of theology

and matters of how the Creator or God works and, indeed, of what God is.

Such questions were addressed fearlessly by thinkers including Nicolas of

Cusa, Johannes Kepler, Leibniz and many others.

Nominalism The understanding that concepts and ideas are merely thoughts and do not

actually exist as the things that they are expressing. Rather, concept and ideas

exist only in the mind not as objects in the physical universe which are subject

to the laws of physics or of metaphysics.

Ontology Part of metaphysics that is more interested in what exists and does not exist,

with an emphasis on entities or “things” expressed by Platonic ideas.

Neoplatonism The outlook that Platonic ideas are valid, truth is discoverable and what is

perceptible via the senses is mere opinion, while truth is discoverable through

Reason. It has the connotation of emphasis on that which the senses cannot

perceive. As a result of this, in part, it has been confused with mysticism and

irrationality. This is correct only if stepwise deduction is considered the only

valid form of rational thought, and many - including Leibniz - would disagree.

3 Van Inwagen, P. “Metaphysics” 2007 in Stanford Encyclopedia of Philosophy

http://plato.stanford.edu/entries/metaphysics/ accessed 21 Feb 2012

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That is, Neoplatonism validates modes of thought other than stepwise

deduction under the umbrella term Reason.4

Neoplatonist A Neoplatonist is an adherent of variants of Plato’s ideas who appeared several

centuries after Plato, or a follower of one of these adherents of Plato.

Neoplatonism is often mixed with Hermetism, early Christian thought and even

Caballa. Leading Neoplatonists include Plotinus, Cardinal Nicolaus of Cusa

and even Cosimo de Medici.5 Some Neoplatonists, such as Plotinus, studied

the Corpus Hermeticum which was attributed to Hermes Trismegistus.

Newtonian The doctrine that empiricism and stepwise deduction from sensory

observations is the way that science should be done. This doctrine downplays

the role of forming hypotheses in science. The rules of Newtonian science

appear to be an extended version of rules of Averroist logic.6

Platonic idea To Kielkopf who undertook a thorough review of Wittgenstein’s foundations of

mathematics, an “absolute platonist [sic]” holds that “the domain of

mathematical objects themselves exist independently of minds.”7 The same can

be said of Platonic ideas more generally, even ones that are not mathematical.

Platonist A Platonist is a follower of Plato’s ideas in their pure form as expressed in

Plato’s own writings such as The Republic. This includes the ability to discover

truth through reason and dialogue, that universal truths exist and the doctrine of

reminiscence.

Pythagorean A follower of Pythagoras, the well-known philosopher. The significance of

being a Pythagorean would be greatly deepened if it were true that Pythagoras

had been a disciple of Hermes Trismegistus as some scholars argue.

Rationalism The doctrine that knowledge of the physical universe is primarily attained

through intellectual reasoning.

4 Petrarca denigrates dialectic saying it is appropriate for students but is immature and silly in a philosopher of

age and experience. Petrarca “A disapproval of an unreasonable use of the discipline of dialectic” Letter to

Tommaso Caloria from Avignon 12 March 1335, pp.134-139 in Cassirer, E., Kristeller, P. O., Randall, J. H. Jr

(eds, trans.) The Renaissance Philosophy of Man Phoenix Books, University of Chicago Press 1948, p.139 5 The historical importance of Nicolaus of Cusa cannot be understated. We quote the closing paragraph of the

introduction to a biography of Nicolaus of Cusa, “In the act of coming to the aid of Pius II and his crusade,

Nicholas of Cusa, the cardinal and longtime confidant of the pope, died three days before him on the road to

Ancona. It was August 11. By then Cusanus had succeeded in participating in, if not actually shaping, nearly

every major issue of the more than half-century that life had given him [1401-1464]. In addition to his career

as an energetic churchman, he also found time to leave a remarkable intellectual legacy that fascinates an

unusually broad range of people to this day, from astronomers and mathematicians to church historians, from

political theorists to theologians and philosophers.” Crowner, D., Christianson, G. (trans. and eds) Meuthen,

E. Nicholas of Cusa: A Sketch for a Biography The Catholic University of America Press, Washington, D.C.

2010 pp.xxv-xxvi. Accessed at http://cuapress.cua.edu/books/frontmatter/MENC.pdf 26 May 2011 6 It is said that Isaac Newton promoted this approach. However, the liveliness of the Neoplatonic environment in

which Newton studied at Cambridge, with people like Boyle around, and the evident mysticism in some of

Newton’s own writings cast doubt on how “Newtonian” he was himself. 7 Kielkopf, C.F. Strict Finitism: An examination of Ludwig Wittgenstein’s remarks on the foundations of

mathematics Mouton, The Hague and Paris 1970, p.32

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Reality (Leibniz’s usage) All that is. This comprises God and the universe. The universe

comprises the physical universe and all that is incorporeal. The physical

universe comprises “body monads” while the incorporeal comprises “soul

monads”. For Leibniz, “body” and objects as people perceive them are not real.

Rather, “coherence is the sign of truth, its cause is the will of God, and its

formal reason is the fact that God perceives that something is the best, i.e. most

harmonious, or, that something is pleasing to God. And so divine will is itself

the existence of things, so to speak.”8 For something to exist, it requires that

God willed it to exist. As far as Leibniz is concerned, the test for humans of

truth is coherence and the best test of coherence is the ability to predict future

phenomena.9

Monad (Leibniz’s concept) A part of reality. An indissoluble piece of substance. Monads are

all that exists, aside from God. Passive monads have perceptions or thoughts

but are sluggish in perceiving and thinking. Active monads have perceptions,

thoughts and memory. There is a continuum from the passive to the active,

with physical matter that is lifeless such as rocks being passive and called body

monads, amoebae being more active, animal souls being still more active, and

human souls being even more active. A collection of body monads controlled

by a mind, such as the body monads comprising the physique of a human

being, have a corresponding soul monad. The soul monad is the same thing as

the mind. The soul monad is linked to the collection of body monads through a

connection called the pre-established harmony. This is a pre-prepared

correlation between the soul monad and the body monads. This makes it appear

that the soul controls the body, when it fact the actions of the two have been

established in advance to ensure that they move in lockstep. This correlation of

actions between the incorporeal and corporeal domains is part of the design of

the universe as the best of all possible worlds.

Substance (Leibniz’s usage in the context of monads) A collective or aggregative

term for what is real. It includes physical and incorporeal substance. Physical

substance includes passive matter and all kinds of radiation. Incorporeal

substance comprises thinking (or “active”) souls, and these govern physical

substance.

“The best” (Leibniz’s usage) The most superior and good way of designing or doing

anything. It is in accord with ideas. It is the standard used by God to make

decisions. It is that which is capable of existing. The Best makes sense over

series events, not in a “snapshot”. Thus, hardship appears to be other than the

Best but in a wider context provides to be desirable and good in the impact on

the clarity and distinctness of the perceptions of minds, and the closeness of

mental conceptions to ideas. In a priori sense this must be the case. In the

context of passive matter such as the motion of planets or of an entire solar

system through a galaxy, and speaking simplistically, the Best manifests itself

as a concept of harmony.

8 Leibniz, G. W. “Body is not a substance” March 1689-March 1690 (?) Sämtliche schriften und briefe series VI

volume 4 Deutsche Akademie der Wissenschaften (ed) p 1637 Strickland, L. (trans.) Leibniz Translations

2009 accessed at http://www.leibniz-translations.com/bodysubstance.htm 6 June 2012 9 Leibniz, G.W. “On the method of distinguishing real from imaginary phenomena” Date unknown in Loemker,,

p.364

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Reminiscence (Leibniz’s usage) The doctrine that all knowledge has always been with

each person, and “acquiring” it is a matter of remembering. This was presented

in Plato’s Meno by a boy with no education solving a geometrical problem

purely by the aid of prompts. Leibniz thought that this made complete sense.

He wrote, “I am in no wise in favour of the Tabula rasa of Aristotle; and there

is something sound in what Plato called reminiscence. There is even something

more, for we have not only a reminiscence of all our past thoughts but also a

presentiment of all our future thoughts.”10 We will refer to a proponent of the

doctrine of Reminiscence as a “Recallist”.

Renaissance humanism The human-centred outlook of the historical period and

movement called the Renaissance. It was especially prominent in Italy but

found all over the Continent and the British Isles. This outlook touched

science, theology, art, literature and many – perhaps all – domains of human

endeavour. It is associated with a renewed interest in Roman and Greek

classics, as well as with an interest in the putative writings of Hermes

Trismegistus. The Hermetic humanist was typically also more inclined towards

classical Hellenic writings. Not all men of letters were interested in all three

categories. Those interested in Roman classics were considered “grammarian

pedants” by those who found truth in Hermetic writings. The Roman (Latin)

humanist hearkened back to the golden age of Cicero and regarded the Middle

Ages as barbarous. By contrast, there were Hermetic humanists such as Ficino

who revered Platonists from the Middle Ages such as Thomas Aquinas.11

Teleology The final or ultimate cause of a phenomenon or event, or the study which seeks

to understand the final or ultimate cause of a phenomenon or event.

Some concepts are best understood in terms of their relationship to other concepts, and some

concepts even exist primarily as a counter to other concepts. We introduce some pairs or

dichotomies, and some triples or trichotomies.

Dichotomy 1: Objectivism vs Subjectivism

An objectivist understands that there are truths that transcend time, space and social norms.

Indeed, the definition of truth is something that holds everywhere, at all times and for all

people. That is, truth is absolute truth. An objectivist may also be called an absolutist.

To a subjectivist, truth varies from person to person and, to an even greater degree, from

culture to culture. In particular, morals vary from person to person and culture to culture. This

variation is valid, and does not detract from the legitimacy of a truth for the person/s for

whom it holds. In short, truth is relative. Thus, a subjectivist may also be called a relativist.

10 Leibniz, G. W. New Essays on Human Understanding in Ladd, G. T. (trans.) The Philosophical Works of

Leibnitz Tuttle, Morehouse and Taylor Publishers, New Haven 1890, p.96 11 Yates 2009, pp.178-181

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Dichotomy 2: Theist vs Atheist

Does a person believe in God or not? A theist believes in a single God and an atheist does not

believe that God exists. Nearly all of the historical thinkers in this dissertation are theists.

What is more important than whether or not a thinker believes in God is their conception of

God. For example, do they consider the mind of God to be unknowable or is God a closed

book who, are far as human are concerned, acts arbitrarily. An atheist typically has to believe

that the universe has always existed, because once the creation of the universe is posited, then

there has to be a Creator. An atheist can concur with a theist who believes in a rational God on

many matters of science, if the atheist believes in a rational universe that has always existed.

Dichotomy 3: Gnostic vs Ignorantist

How close can we come to God? Gnostic means that we can have direct experience of God.

Ignorantist means that we can only ever indirectly understand God; while we can approach

God and get closer and closer, we will always be infinitely distant from God. We coin the

term ignorantist based on the title of Nicolaus of Cusa’s De Docta Ignorantia (“On learned

ignorance”). Petrarca before Cusa wrote on ignorance12 and it is known that Cusa had a copy

of Petrarca’s work.13

Trichotomy 1: hylarchic vs mechanist vs animist

How does God relate to or connect with the physical universe? The hylarchic principle is that

God is in the universe, giving the physical universe a real spiritual quality. God is intervening

in the functioning of the universe from moment-to-moment, perhaps in a structured or ordered

way. To a mechanist, God is not in the universe but made the universe so that it can function

without God’s ongoing intervention.

An animist believes that the physical universe contains divine entities; indeed, that everything

in the universe is a divine entity in itself. For example, even a rock is not only alive but is a

spiritual entity with divine qualities. Pantheism is similar to animism. A pantheist considers

the world as a whole to be a single, divine entity. There are no pantheists in this dissertation.

Trichotomy 2: Neoplatonist vs Rationalist vs Empiricist

A Neoplatonist or “new Platonist” considers that there is a world of ideals which can be

discovered and understood only by the mind. These ideals or perfect versions of things are

templates for what we find in the physical world. The physical world comprises combinations

of ideals so complex that it appears to not mirror the world of ideals at all. A Neoplatonist is

necessarily an absolutist.

Rationalism says that truth can be discovered by way of thought without any sensory input or

physical observation. Clearly, a Neoplatonist is a rationalist, but a rationalist is not necessarily

12 Petrarca “On his own ignorance and that of many others” c.1368, pp.47-133 in Cassirer, E., Kristeller, P. O.,

Randall, J. H. Jr (eds and trans.) The Renaissance Philosophy of Man Phoenix Books, University of Chicago

Press 1948 13 Brand, P. Cambridge History of Italian Literature Cambridge University Press 1999, p.134. Cusa continues

Petrarca’s programme of demonstrating that intellect as exercised by an intelligent commoner can be more

effective than the formal reasoning promoted by the scholastics.

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a Neoplatonist. An empiricist believes that what is known comes to a person via the physical

organs of their five senses.

An empiricist cannot be a Neoplatonist because a Neoplatonist believes that what the senses

perceive is no different from mere opinion and is therefore of no value in uncovering truth. A

Neoplatonist could be at least a quasi-empiricist because the sensory input might help prompt

or stimulate thoughts that help lead us to truth; however, a Neoplatonist cannot be entirely

empiricist because thought – not sense perception – must necessarily play the crucial

mediating role before truth may be uncovered.

The relationship between rationalism and empiricism is the same as the relationship between

Neoplatonism and empiricism.

Relationship of concepts to one another

Relations arising from Trichotomy 2 which fall out from the definitions are:

Neoplatonist ==> Rationalist

Empiricist ==> ¬ Neoplatonist

Empiricist ==> ¬ Rationalist

Neoplatonist ==> ¬ Empiricist

Rationalist ==> ¬ Empiricist

Leibniz’s “empiricism” is simply that sensory observation prompts thoughts and checks

reasoning, including the soundness of reasoning. Empiricism says that the senses give us

knowledge and that thoughts are only needed to organise the knowledge that the senses give

us. We see that this is at odds with Leibniz’s position as explained in his New Essays on

Human Understanding.

The doctrine of Reminiscence is connected to one’s conception of the soul, especially the

continuity, antuiqity and origin of the soul and its knowledge. Therefore, Reminiscence holds

a tenuous connection to the other concepts:

Rationalist =/=> Recallist

Recallist =/=> Rationalist, yet Leibniz is both Rationalist and Recallist.

Platonist ==> Recallist, from Meno and this is Leibniz’s position

Neoplatonist =/=> Recallist, though some were, like Leibniz.

Definitions do not do justice to the richness of the ideas expressed by the terms which are best

read in a context. However, the intention of this background is to ensure that the reader has

seen the terms once and has some familiarity with them when they are first encountered in

this dissertation.

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Chapter 1: Introduction

The thesis begins with the historical milieu in which Leibniz worked, and the earliest projects

he was engaged in after meeting Christian Huygens. Next we situate the goals of scientific

discovery which were being debated in Leibniz’s lifetime in terms that crossed over into the

theological. We then turn to the philosophical battles over how science should be conducted

into which Leibniz pitched. With that background, we will be ready to consider scientific

method including how philosophical positions influenced the way in which scientific

problems were approached. The questions addressed then broaden, quite naturally, into the

broadest questions such as the role of thought in science and which kinds of notions should be

encouraged in scientific endeavour and which not.

This argument in this thesis agrees with how Jürgen Lawrenz’s 2007 PhD thesis at the nearby

University of Sydney Leibniz: Double-Aspect Ontology and the Labyrinth of the Continuum

situates Leibniz among these three ’isms:

1. Realism: objects and events exist in the universe, and their properties and relations

obtain, irrespective of our beliefs about them and independently of our ability to

discern them;

2. Idealism: the world is comprehended wholly in the form of mental representations;

3. Phenomenalism: our knowledge of the world is mediated entirely by sense

impressions.

Lawrenz says that Leibniz is realist, idealist and not phenomenalist, and nothing in this thesis

contradicts those outcomes. That Leibniz is realist is almost immediate. That he is idealist

follows from the exclusive place given to mind in understanding and even – via the pre-

established harmony – in experience. That Leibniz cannot be phenomenalist also follows from

his conception of the role of mind.

Neoplatonism and the ideas that it encompassed is so important in understanding the context

in which Leibniz worked that it deserves its own chapter. So in Chapter 2, “Neoplatonism and

the awakening of science”, Neoplatonism is introduced along with the many ideas that are

encompassed by its contribution. This includes proto-science, “magic” and an interest in the

Hermetica or the writings of Hermes Trismegistus. Equally if not more important, but

secondary in this thesis, is the revival of interest in Aristotle, and the interpretation and

reinterpretation of Aristotle by people subject to such processes as a millennium of

Christianity and several centuries of Islam. What was significant about the renewed interest in

Hermetica and a serious approach to magic was a structured approach to what Yates calls

“operations” or human intervention in the physical universe.14 This leads to the next chapter.

In Chapter 3 “Ushering in modernity”, Leibniz’s role in nascent nation-building efforts of

Louis XIV are examined. It is argued that the expression of rationalism in machine-building

and inanimate power sources define the beginning of modernity. If this argument is correct,

then it follows that Leibniz was a central figure in the commencement of modernity. In

14 Yates 1964, pp.146-147

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modernity, the engagement in ever more efficient and powerful kinds of “operations” is

systemised and given a central place in society, policy and all aspects human endeavour. In

early modernity, the nature of Man as magus was first institutionalised like never previously

in history with the construction of machines and projects to “operate” on an unprecedented

scale for the benefit and ongoing realisation of Man’s purpose and role in the universe.

In Chapter 4 “Idea of truth”, the pursuit of truth is introduced with the reason versus

empiricism dichotomy which is indistinguishable from idealism versus phenomenalism. The

chapter introduces scientific personalities of decisive importance to the subsequent history of

science: Johannes Kepler, Galileo Galilei, Paolo Sarpi and Isaac Newton. It is explained that

for Leibniz the search for scientific truth is inseparable from the investigator’s ability to

understand the nature of the Creator of the universe. This is a Neoplatonic orientation.

Contrary to this, a junction in science is found in Paolo Sarpi in whom a stream separate from

the Neoplatonists that emphasises Empiricism, and which coincides with Atheism, is

introduced into Western science.

In Chapter 5 “The Neoplatonist and Empiricist schools”, the concept of calculation natural

evolution of the Neoplatonic school is introduced. This includes calculation with

metaphysical concepts. Lawrenz writes of Leibniz that one can, “Open any page of his

writings to see physics happily consorting with metaphysics – it is the pattern of his thinking.”

In this chapter, it is explained that Leibniz had no choice in this, for it is an inexorable

consequence of his integrated conception of how the capabilities of the human mind

understand and commandeer reality. Leibniz regarded mathematical calculation as but one

aspect of reasoned thought. Leibniz promoted the project to construct a Universal

Characteristic that would supply an answer to any question, not only in physical science but

also about moral differences, through unambiguous calculation.

In Chapter 6 “Discovery and deduction”, Leibniz’s recommended process for discovery is

described. The Leibnizian prescription is to hold all the considerations relating to a problem in

one’s mind in a single thought. It takes considerable time and thoroughness to be able to

achieve this. This is posited as a top-down method in contrast to stepwise reasoning also

known as discursive reasoning or, in some contexts, as dialectic. Much is owed to Nicolaus of

Cusa’s De Docta Ignorantia or “On Learned Ignorance” which argues that stepwise reasoning

does not lead to new knowledge. Rather, the approach that leads to breakthroughs is to seek

the higher hypothesis which subsumes a problem and its related sub-problems – such as all

previously understood phenomena and a new class of anomalous observations – in a new

whole with a simpler but more widely-encompassing explanation. To hold all considerations

on some topic in one’s mind in a single thought is the way Leibniz thinks that God works.

This is considered in the next chapter when God’s choosing of “the Best” of all possible

universes is dissected.

In Chapter 7 “Science by thought, reality and substance”, Leibniz’s theory of reality in toto –

physical and incorporeal – is put on the table. Its comprehensiveness is astounding and would

be more astounding had multiple attempts not been made in the past. Liberty is taken in many

footnotes to point out similarities between Leibniz’s theory and Hermes Trismegistus.

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Leibniz’s doctrine that this physical universe is the best of all possible worlds is part of his

scientific conception of the universe and of humanity’s role in it. It is shown that mathematics

is necessarily incomplete unless a rigorous conception of “the Best” can be formulated. The

chapter is left hanging with important open questions which suggest that the a priori method

is the only way to proceed when faced with really fundamental questions.

In Chapter 8, it is explained how the Leibnizian framework draws mind and humanity into the

domain of physical science. The thoughts of soul monads have a role in the physical universe.

The chasm between the perceptions of minds and the actions of body comes into view.

Leibniz spanned this divide with pre-established harmony, which requires God to intervene

every instant to mediate between mind and body in “the Best possible way”. The fact that God

mediates at all seems to be a glaring self-contradiction by Leibniz since he always held that

the Best possible universe cannot require God’s ongoing intervention. The contradiction is

resolved by the fact that the universe is re-created in every instant according to the thoughts of

soul monads, via the agency of the pre-established harmony which God shepherds along in

the best possible way.

Until science is expanded to subsume the pre-established harmony, science is – to a

significant degree – condemned to being an exercise in shadow boxing, or pursuing truths

lacking in context and lacking in metaphysical basis. Arguably, we cannot even understand

the mechanism of the physical universe without incorporating the pre-established harmony

into physics. The fact that the universe unfolds in “the Best possible way” implies that God

has built some kind of engine of intention into the physics of the universe. Of course, one

obvious intentional part of the universe is humankind itself. Thus, the status and role of

humankind as a physical force in the universe – as a law of physics, so to speak – warrants

attention in future research.

In Chapter 9 “A priorism in science”, three successful scientific projects that relied primarily

on a priori thought are described. The examples chosen are the infinitesimal, non-Euclidean

geometry and elliptical orbits in a heliocentric solar system. In all of these, but especially in

the first and third, the thinkers concerned pursued a priori methods deliberately, and were

self-conscious advocates for their own approach. In developing non-Euclidean geometry, the

thinkers were departing from the Fifth Postulate in a conscious effort to create a geometry that

is self-consistent and functional. Beyond that, Riemann in particular understood that any new

geometry must be viable in the physical universe. For Leibniz, the physical universe is the test

of truth because, as explained above, the physical universe expresses “the Best”.

In the concluding chapter, the humanist project in which Leibniz was engaged is discussed. It

is explained how his metaphysical and philosophical work, and his science and mathematics,

furthered the aims of this project. This project refines and furthers a conception of Man as

magus which was “modern” for the 17th and 18th Centuries. This survives today in the policies

of scientific-industrial nation state. Such policies were seen in early form under the leadership

of Louis XIV and Tsar Peter the Great. It is not a coincidence that Leibniz played an active

role in the nation-building efforts of Louis XIV’s France and Tsar Peter the Great’s Russia, as

described in this thesis.

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Chapter 2: Neoplatonism and the awakening of science

Introduction

It will be argued in the course of this thesis that Leibniz represented a continuation of the

influence of Neoplatonism as well as being a conscious referent to the original writings of

other movements and schools of thought, such as those of Plato, Aristotle and their followers.

When referring to actual figures such as Plato and Aristotle, the meaning is clear. What,

though, is Neoplatonism? The term encompasses a body of intellectual disciplines, mindsets

and networks of co-thinkers. I think of Neoplatonism as a movement that helped create much

larger shift, like lava flowing between two tectonic plates. To use phrases that might mean

little at present, Neoplatonism includes Hermetism, Cabala, medieval magic, memory

methods, the use of symbols and construction of languages, alchemy, proto-science, proto-

engineering and a bit of Platonism.

After the fall of Rome in 476 CE,15 intellectuals looked to Athens, Egypt and other ancient

cultures for wisdom and to increase their knowledge in almost any and all domains. Those

earlier cultures were regarded as more enlightened, virtuous and generally elevated than the

present. As Yates put it, the farther back in history a seeker explored, the purer and better the

minds found. The closer to the present, the more benighted and corrupt. Even the standout

philosopher of Rome, Cicero, leaned heavily on the philosophers of Athens. De Natura

Deorum reflects Plato’s The Republic in many ways. After Rome, the tendency and indeed the

imperative to look backwards in time increased.

The first Neoplatonists were “new Platonists”

The takeover of Athens by the Romans did not eliminate adherents of Plato. Indeed, Plato’s

Academy continued to teach students. The Greek thinkers Plotinus (c.204/5 – 270 C.E.),

Porphyry (c.234–305 C.E.) and Iamblichus (c.242-327 C.E. or 250-330 C.E.16) are regarded

as the founders of Neoplatonism. These can be regarded as the first kind of “Neoplatonist”.

The term has a literal meaning in the sense of a series of teachers known for their

interpretations of Plato. Indeed many if not all actually taught in Plato’s academy. This line of

teachers included Speusippus of Athens was the son of Plato's sister Potone; he became head

of the Academy when Plato died in c.348/347 BCE and remained its head for eight years.17 In

the early 4th century C.E., Iamblichus moved the major Neoplatonist school from Rome to

Syria. Thereafter, Neoplatonism flourished mainly in the Eastern Roman Empire, with centres

in Athens, Alexandria, and Pergamum (now in Turkey). In the 5th century C.E. one of its

greatest teachers was Proems, at Athens. This was also where the well-known Neoplatonist

Proclus (c.412–485 C.E.) taught. During the same century the writings of St. Augustine firmly

established its influence in Christian theology. St Augustine embraced some parts of 15 This is Edward Gibbon’s date which is conventionally accepted. 16 Accessed at http://www.goddess-athena.org/Encyclopedia/Friends/Iamblichus/index.htm on 5 April 2012 17 Hicks, R.D. (ed.) Diogenes Laertius Lives of Eminent Philosophers IV 1 accessed at

http://www.perseus.tufts.edu/hopper/text?doc=Perseus%3Atext%3A1999.01.0258%3Abook%3D4%3Achapt

er%3D1 20 April 2012

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Neoplatonist teaching while filtering out parts considered to be contrary to his Christian

theology.

The Neoplatonists were not unmolested by the powers that were. While Constantine was the

first Christian emperor of Rome, his nephew Julian who succeeded him was a Neoplatonist, a

pupil of Aedesius, who had in turn been taught by Iamblichus.18 Emperor Julian was

sympathetic to Neoplatonism but his successor Emperor Theodosius was not. Under

Theodosius, the leading Neoplatonist teacher Hypatia was dragged from the academy and

murdered in 414/415 C.E. (there are differing accounts of the year) by a mob of Christian

monks under the control of Bishop Cyril of Alexandria. Ostensibly, Hypatia’s crime might

have been to attempt to publicly hold the light of reason to the “metaphysical allegories from

which Christianity had borrowed its dogmas”.19 It is likely that the threat posed by

Neoplatonism was much deeper, and that the real threat was not to Christianity but to the

Roman Empire and to the system of Empire in general. However, these ideas are speculative

and further discussion is beyond the scope of this thesis. Finally, under Emperor Justinian, the

last seven significant Neoplatonic teachers Hermias, Priscianus, Diogenes, Eulalius,

Damaskias, Simplicius and Isidorus were unable to continue the Neoplatonic school in

Athens.

The early Neoplatonists just mentioned were aware of the Egyptian writings especially those

of Hermes Trismegistus and there were Neoplatonists who absorbed Christian mysticism. The

first Christian Neoplatonist to write in Latin was Victorinus, who was converted to

Christianity in 360 C.E.20 In the 400s C.E., Pseudo-Dionysius, expounded a Christian

mysticism based on Neoplatonism that influenced later Christian mystics. Four centuries later,

a famed medieval Neoplatonist named John Scotus Erigena; he was the Irish theologian of the

9th century C.E. The Cambridge Neoplatonists are a group from the late 17th century C.E.

who sought to counteract the scientific materialism then prevalent.21

Arab philosophers

Following the first Neoplatonists, the Arab philosophers were active for at least a century or

so were also active in reviving ancient philosophy both Greek and Egyptian. This was an

intermezzo between the various wars and wrecking operations that beset the West between the

fall of the Roman Empire and the Renaissance.

Avicenna (Ibn Sina 980-1038) wrote on logic and philosophy, while also making original

discoveries in medicine. Avicenna is often cast as Platonist mediated by the

Neoplatonists,22,23,24 but he also adopted ideas from the Stoics such as Zeno and Chryssipus,

18 Accessed at http://www.wisdomworld.org/setting/hypatia.html on 5 April 2012 19 Ibid. 20 Inge, W.R. Christian Mysticism Plain Label Books, Chumley P. Grumley (series ed.) 1956 pp.153-154 based

on The Bampton Lectures 1899 delivered before the University of Oxford 21 Accessed at http://philosophos.hubpages.com/hub/neoplatonism on 7 April 2012 22 Wisnovsky, R. Avicenna’s Metaphysics in Context Cornell University Press 2003, p.64 23 Goodman, L.E. Avicenna Cornell University Press 2005, p.56 24 Harrison-Barbet, A. “Avicenna” in Philosophical Connections: Islamic Neoplatonism accessed at

http://www.philosophos.com/philosophical_connections/profile_036.html 20 April 2012

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and from Aristotle and his disciples.25,26 Avicenna also tried to reconcile the orthodox Islamic

doctrine of the “theologians” of his culture with the philosophers. Al Ghazali (1058-1111)

ridiculed attempts of writers such as Avicenna who tried to reconcile Islamic doctrine with

philosophy. However, he spared neither the Islamic doctrinal theologians nor the

philosophers. In talking about the philosophers, he was targeting contemporary proponents of

Aristotelian doctrine as they interpreted it. Platonic ideas seemed to be outside his purview.27

It was not only the “third force” of Plato that Al Ghazali let alone. Kilcullen at Macquarie

University says that the Muslims were “neo-Platonists” presumably that they nearly all were

neo-Platonists, though it is unclear where this means students of Plato or whether it means

Neoplatonists.28 There was also the “big influence of Hermetic and gnostic literature and

ideas on the Arabic world and particularly on the Arabs of Harran.”29 Further, “Talismanic

magic was practised by those Arabs, and the influence came through the Sabeans who were

immersed in Hermetism, in both its philosophical and its magical aspects.”30 The Picatrix was

probably written in the 12th Century, and while it lists magical images and procedures, it does

so in a philosophical setting similar to if not borrowed from the Corpus Hermeticum and the

Asclepius.31 The Picatrix circulated during the Italian Renaissance and references to it are

found in the writings of Pico the younger, among others. A copy was found in the library of

Pico Della Mirandola (1463-1494). It was included in a list of works “codex” on magic

copied in 1488 in Kraków, probably by a university student referred to as Egidius. The codex

includes Hermetic works and the Picatrix. From the commentary given in the codex, one

commentator concludes that “in all probability he [Egidius] knew the content of the

Picatrix”.32 Rabelais (c.1494-1553) came to its defence to it in one of his famous satires,

Pantagruel. Rabelais poked fun at those who shun the Picatrix by referring to “Father Devil

Picatrix, doctor of the faculty diabolical”. (Pantagruel III, 23)

While the Picatrix was written in the 1100s, we would expect it not to have arisen

spontaneously but to more likely have followed a century and probably more of thought,

teaching.

During the 1100s Averroes (Ibn Rushd, 1126-1198) which was guided or at least given initial

direction from Abu Bakr (Ibn Tufayl) chief physician to the monarch Abu Ya‘qub Yusuf

(c.1168-1169). Averroes was from an influential family possibly with a certain religio-

political orientation. For example, the distinctions of his grandfather Abul-Walid (1058-1126)

was that he was chief justice, wrote a definitive legal text, and leaned on the monarch Ali Ibn

25 Zabeeh, F. (ed. and trans.) Avicenna’s Treatise on Logic Martinus Nijhoff, The Hague 1971. For example, the

definition of “proposition” and the meaning of “indefinite” pp.20-21 nn.6-10, and p.23 n12 26 Supra nn.23-25 27 Bergh, S. van den Averroes’ Tahafut Al-Tahafut (The Incoherence of the Incoherence) Trustees of the E. J. W.

Gibb Memorial, London http://www.muslimphilosophy.com/ir/tt/index.html 7 April 2012. See the

introduction. 28 Kilcullen, R.J. Lectures for PHIL252 Medieval Philosophy, Tape 7 Al Ghazali and Averroes Macquarie

University, accessed at http://www.humanities.mq.edu.au/Ockham/x52t07.html 7 April 2012. See Kilcullen’s

full list of lectures here http://www.humanities.mq.edu.au/Ockham/kilcullen.html accessed 7 April 2012 29 Yates 1964, p.49 30 Ibid. 31 Ibid., p.47 32 Láng, B. Manuscripts of Learned Magic in the Medieval Libraries of Central Europe Magic in History Series,

The Pennsylvnia State University Press, 2008 pp.33, 35

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Yusuf to be tougher on the Christians of Andalus.33 Averroes ostensibly wrote in response to

Al Ghazali taking exception to his ridicule of Aristotelian philosophers saying that those

philosophers and Al Ghazali had not understood Aristotle. Averroes used persuasion not

attack. His main target seemed to be those engaged in the practice of law. Lawyers, judges

and clerics alike were wedded to Islamic doctrinal theology in the practice of law to the extent

that even the monarch Abu Ya‘qub Yusuf never publicly announced his support for

philosophy. Nonetheless, possibly under the persuasion or at least influence of Ibn Tufayl

himself, the monarch Abu Ya‘qub Yusuf allowed Ibn Tufayl to commission Averroes to write

commentaries on Aristotle that were accessible to the reading public.34

From the 9th Century up to Averroes there had been a cloud of suspicion alternating between

theology and philosophy. Ibn Masarra (883-931 C.E.) is regarded as the first Andalusian

philosopher. The zeitgeist was against them, and so he and his disciples only survived by

living as hermits. Hourani writes that Ibn Masarra introduced a pseudo-Empedoclean

pantheism.35 Empedocles (c.494/5-435 BCE) is one of the few pre-Socratic philosophers

whose original writings have been found.36 In the late 11th Century and into the 12th Century,

philosophy found increasing favour to the detriment of theology. In fact, the monarchs

encouraged the study of Malikite law and banned theology.37 Malikite law is a school of law

founded by Malik ibn Anas (c.710-795 CE) which recognizes a range of sources of law.38 Ibn

Bajja better known as Avempace (c.1095-1138 CE) was the first Andalusian philosopher to

make direct use of the works of Plato and Aristotle. Philosophers were still subject to

suspicion. For example, ibn Wahib a contemporary of Avempace, ceased to speak about

philosophy openly out of fear for their lives.39 It appears that ibn Sina also known as Avicenna

attempted to play a conciliatory role but to Al Ghazali both the theologians and philosophers

were wrong as well as being irreconcilable. Al Ghazali is best known for his Tahafut al

falasifa (“The Incoherence of the Philosophers”). While this sounds like a dogmatic and

politically-charged title, Al Ghazali was not a dogmatic contrarian. He wrote many other

works which describe, explain and grapple with both theology and philosophy.40 When

Averroes replied to Al Ghazali 80 years later, it was only to defend Aristotle not for the most

part any other philosopher and not (Islamic) theology.

It has been mentioned that Picatrix reached Europe and had some Hermetic effect on

intellectuals there centuries later. So too did Avicenna, Al Ghazali and Averroes. The reception

of Averroes was not entirely favourable in the increasingly Christianized Europe due in part to

Averroes’ advocacy of ideas such as that the universe has always existed and was not created,

33 Hourani, G.F. (ed,. trans.) On the harmony of religion and philosophy : a translation, with intro. and notes, of

Ibn Rushd's Kitab fasl al-maqal, with its appendix (Damima) and an extract from Kitab al-Kashf 'an manahij

al-adilla Luzac London 1961, p.14 34 Ibid., pp.12-19 35 Ibid., p.7 36 Accessed at http://history.hanover.edu/texts/presoc/emp.htm and http://plato.stanford.edu/entries/empedocles/

7 April 2012 37 Hourani, G.F. (ed,. trans.) On the harmony of religion and philosophy Luzac London 1961, p.7 38 Accessed at http://faculty-staff.ou.edu/V/David.R.Vishanoff-1/I-terms/Malikites.htm 7 April 2012 39 Hourani, G.F. (ed,. trans.) On the harmony of religion and philosophy Luzac London 1961, pp.8-9 40 A readable and apparently thorough summary of Al Ghazali’s works is at this page

http://www.ghazali.org/articles/gz1.htm accessed 7 April 2012

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and the impermanence of the individual human soul.41 In 1270, Saint Thomas Aquinas took

the trouble of writing “On there being only one intellect” in Paris while occupying a

Dominican chair of theology as Regent Master. Aquinas argued that intellect is a faculty of

the soul that animates the human body, and that there is not only a single separate intellect

that suffices for and furnishes all humans, but that each individual human soul has its own

intellect.42 Moreover, Aquinas argued, Aristotle would have agreed whereas Averroes had

misinterpreted Aristotle. Aquinas presented Aristotle as consistent with Christian metaphysics

on essential points.

Averroes is sometimes presented as having washed over Europe and fully infiltrated

institutions such as the University of Padua which became a “stronghold” of Averroism.

Martin explains that the truth is not so simple. (Martin, C. 2007) Intellectuals were as averse

to an Averroes dogma as they were to any other. Rather, Averroes was often quoted in order to

indirectly assert a secular orientation without inviting arrest, torture and death at the stake by

the Inquisition.43 Indeed, it is strange that no text by Averroes was placed on the Vatican’s

Index Librorum Prohibitorum (“List of Prohibited Books”) especially given Aquinas’

thorough case against the coldly argued anti-Christian position of Averroes’ Middle

Commentaries on Aristotle’s De Anima (“On the soul”).

Returning to the influence of pre-Athenian thought, we have already mentioned the Corpus

Hermeticum. This was and is ascribed to Hermes Trismegistus though the circuitous route

between Hermes Trismegistus and the documentation of Hermes’ teachings in the Corpus

Hermeticum is subject to debate. It is reported by some that Hermes was Egyptian,44 and he is

sometimes associated with the Egyptian god Thoth with the head of an Ibis. It has been

argued that there were three different Hermes Trismegistuses the third of whom was the

teacher of Pythagoras, while others dispute whether Hermes was ever a real person.

Hermeticum and magic in Europe

It has already been mentioned that the Arabs of Harran were steeped in Hermetic lore at least

from the 12th Century when the Picatrix was written.45 The Picatrix was in part a magical text

with symbols that can be used as talismans.46 In the 13th Century, Abulafia wrote a tract of

Cabalistic symbols and combinations of letters as an aid to understanding, meditation and

memory.47 In 1305, the Picatrix was translated into Latin by a scholar named Sloane.48 Yates

quotes at length from Book IV Chapter 3 of the Picatrix:

41 McInerney, R. Aquinas against the Averroists: on there being only one intellect West Lafayette, Purdue

University Press 1993, pp.71-99 42 Ibid., introduction p.ix 43 Martin, C. 2007 pp.6, 18-19 44 Barrett, F. The Magus Book III: Biographia Antiqua London 1801 pp.150-151 Accessed at http://www.sacred-

texts.com/grim/magus/ma255.htm 9 April 2012. However, as the Sacred Texts website itself notes, “The

biographical section has been deprecated by authorities such as Waite, and it's not even certain that it was

written by Barrett; it may have been added as filler by the printer.” Barrett’s book was re-published in 2003

by Kessinger Publishing under the title “The Magus a Complete System of Occult Philosophy”. 45 Yates 1964, p.49 46 Ibid., pp.51-52 47 Ibid., p.93 48 Ibid., p.50 n.1

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There are among the Chaldeans very perfect masters in this art they affirm that

Hermes was the first who constructed images by means of which he knew how to

regulate the Nile against the motion of the moon. This man also built a temple to the

Sun, and he knew how to hide himself from all so that no-one could see him, even

though he was inside it. It was he, too, who in the east of Egypt constructed a City

twelves miles long… Around the circumference of the City he placed engraved images

and ordered them in such a manner that by their virtue the inhabitants were made

virtuous and withdrawn from all wickedness and harm. The name of the City was

Adocentyn [in the Arabic original, al-Ašmūunain].

Giordano Bruno 279 years later wrote about the Greek origins of European civilisation

affirming that its origins were not Judaic but Chaldean. In Bruno’s work The Expulsion of the

Triumphant Beast published in 1548, he wrote, “Do not infer that the sufficiency of Chaldean

magic comes from Cabala; indeed, there has never been anyone who could pretend that the

Egyptians could have taken any principles from the Judaic corpus.”49

Giordano Bruno

Giordano Bruno was a philosopher, activist, teacher, Dominican friar and expert on the art of

memory. He was born in Nola Italy in 1548 and burned at the stake in 1600. He began a

period of almost 20 years as a fugitive from the Inquisition at the age of 28 when he fled the

Dominican monastery where he was studying following a tip-off that he would be

apprehended by the Inquisition for possessing forbidden books. He then lived as an itinerant

teacher and writer. Patronised by Henri III of France, he went to London as an organiser and

kind of emissary with a letter of introduction from Henri III to the French Ambassador. This

introduction afforded Bruno diplomatic protection. While in England, Bruno was active in

Hermetic and Neoplatonic circles, with known highlights including a lecture at Oxford and

strong relations with Fulk Greville a teacher of Shakespeare. It is believed that Bruno taught

his art of memory to Greville who passed it on to Shakespeare. Elizabethan actors were

required to have powerful memories due to the short times needed to learn lines and the fact

that a single actor would typically play many roles in a play. While acting circles were

necessarily full of skilled mnemonists, Shakespeare was respected even in acting circles for

his memory. It is not too much of a stretch to attribute this to Bruno’s memory methods.50

Bruno is credited with bringing a modern outlook on the universe, as full of stars which were

suns like our own. Each sun, according to Bruno, had many planets and many of those were

peopled with intelligent beings who probably worshipped their own gods. Like that of most of

the people mentioned in this thesis, the story of Bruno is an epic in itself. We introduce Bruno

because he is mentioned in this thesis in connection with the revival of the teaching of

Hermes, the role of a rational kind of magic, and the use of symbols as an aid to thought.

49 Paraphrasing the translation in Rowland, I.D. Giordano Bruno: Philosopher and Heretic University of

Chicago Press 2009, p.59 of a passage in Giordano Bruno’s Expulsion of the Triumphant Beast 1584 50 White, M. The Pope and the Heretic: The true story of Giordano Bruno, the Man Who Dared to Defy the

Roman Inquisition Harper Collins 2001

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Consistent with Bruno’s view is one circulating in the circles of “New Age spiritualism” that

the wisdom of the Cabala is merely what the Jews took with them of Egyptian wisdom when

they left Egypt.51

Magic, talismans, symbols, languages and the art of memory in the 16th Century were on

some occasions treated separately and at other times together. There are many studies that

show why it is artificial to separate these domains. Credit goes to Yates for showing how these

threads were drawn together by Bruno in Art of Memory.52 However, there were many figures

other than Bruno, such as Marsilio Ficino, Pico della Mirandola, perhaps nearly every

European thinker from the Neoplatonists up to Leibniz who would not have been able to

study one area without examining the others too. This does not mean that every contributor to

language such as Dante or to the art of memory such as Bruno was an aspiring magician.

Michael White writes that though Bruno “was fully cognizant of the power of magic ritual

and the occult tradition”, nonetheless Bruno “was convinced by very little of the occult

canon.” In fact, “he knew much of it was superstition, wild fantasy, and wishful thinking.”

However, it did indirectly play a role. “To Bruno, as to many great thinkers after him, the

occult was primarily a useful tool, a key that would open doors into arenas of thought and

hidden depths of the human psyche. Along the occult path he found tracks, roughly hewn, that

led to revelation and inspiration. Alchemy held no interest for Bruno; he was never motivated

by experiment and was not drawn by the search for the philosophers’ stone, the dream of

limitless wealth. Neither did he practice ritualistic magic or necromancy; indeed, he often

mocked practicing astrologers and many of the irrational precepts of witchcraft.”53

Hermes in Europe by mistake

In the first half of the 15th Century, Cosimo de Medici was financing expeditions for ancient

texts and the translation of those texts obtained. While Athenian writings such as those of

Plato or Aristotle or their disciples were valued, the earlier philosophers of Egypt, the

Chaldeans and others were even more highly valued. As mentioned above, the perception was

that more ancient meant purer and better. More than a hundred years after Medici, Bruno

continued to hold that the best of European philosophy emanated from Egypt, and not merely

because “older is better” was a catchy epithet. He understood that Ancient Egypt was the

source of Greek philosophy, implying that even the Greeks were a dilution of the best of

Egypt. In his The Expulsion of the Triumphant Beast published in 1584, Bruno wrote, “ We

Greeks recognize Egypt, the great monarchs of literature and nobility, as the parents of our

epics, metaphors and doctrines”.54,55

51 For example, http://www.amaluxherbal.com/bnewbooks/hermes%20trismegistus.html accessed 9 April 2012 52 Yates, F. Art of memory University of Chicago Press, 1966 53 White, M. The Pope and the Heretic: The true story of Giordano Bruno, the Man Who Dared to Defy the

Roman Inquisition Harper Collins 2001, pp.67-68 54 Giordano Bruno Nolano, Spaccio de la bestia trionfante. Stampato in Parigi MDLXXXIIII, in Dialoghi

filosofici italiani, a cura di Michele Ciliberto, Monciodadori, Milano 2000 55 Paraphrasing the translation from Rowland, I.D. Giordano Bruno: Philosopher and Heretic University of

Chicago Press, Chicago 2009, p.59, originally published in 2008 by Farrar, Straus and Giroux

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Returning to Cosimo de Medici, the monk Leonardo da Pistoia sent manuscripts of the

Corpus Hermeticum, which were putatively written by Hermes Trismegistus himself to

Medici. Medici sent them on to Ficino in c.1462 asking Ficino to pause on the translation of

Plato and to translate the Hermetic manuscripts as quickly as possible so that Medici could

read them for he was terminally ill.56 Ficino’s translations of the works were published in

1471. The works were the Asclepius or De voluntate divina “On Divine Will”, the Pimander

or De sapientia et potestate Dei “On God’s Wisdom and Power”, and the Asclepii

Definitiones.57 Ficino (1433-1499) holds a significant place in the history of theology,

religion, magic and philosophy.

In 1614, Isaac Casaubon proved that the Hermetic manuscripts were no older than the second

or third century C.E.58 However, by that time, they had already had 140 years to transform the

thinking of intellectual and influential circles throughout Europe.

To use Yates’ words, Hermes Trismegistus, through these proxy writings, authorised by his

antiquity the revival of forms of magic.59 That revival included the surrounding philosophy

including doctrine of the universe and the active place of humankind in it.

Natural magic

Ficino the translator of the manuscripts for Cosimo de Medici has an enthusiasm for “magna

naturalis” or natural magic or the magic of nature which, ultimately, can only mean the

science or, at least, proto-science albeit undoubtedly with a mystical overlay. Pico della

Mirandola began his career under Ficino’s influence and inherited Ficino’s enthusiasm for

magia naturalis.60 Pico perhaps partly due to the Judaic origins of the Old Testament account

of Creation in the Torah effected a marrying of Hermetic and Cabalistic magic. This, writes

Yates, “was to have momentous results, and the subsequent Hermetic-Cabalistic tradition,

ultimately stemming from him [Pico], was of most far-reaching importance.”61

Many have heard of a controversial 900 theses published in Rome centuries ago. It was Pico

who wrote them and in 1486 took them to Rome proclaiming that he was ready to prove in

public that they were all reconcilable with one another. Twenty-six of the theses were on

Cabalist and/or natural magic. One thesis says the old-style kinds of magic should be

forbidden, but that magia naturalis is a good, allowable magic. In another thesis, Pico says

good magic is in part the practical science of nature.62

In his survey of “learned magic” according to manuscripts from Central European medieval

libraries, Láng writes “It might sound surprising, but ‘necromancy’ in [one of its meanings]

was long a successful applicant for denoting a widely accepted part of science. The great

56 Yates 1964, p.58, Yates 2009, pp.13-14 57 Jaroszyński, P. Science in culture Rodopi B.V., Amsterdam, New York 2007, p.139 58 Ibid. 59 Yates 1964, p.58, Yates 2009, p.63 60 Ibid., original 1964 edition, pp.84, 87-88 61 Ibid., pp.86 62 Ibid., pp.87-88

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summary of Arabic magic, the Picatrix, defines it in a rather wide and naturalistic sense as the

science dealing with all the things that are hidden from the senses or from the intellect, the

functioning of which most people do not understand.”63

While Ficino obscured the Hermetic origins of the magia naturalis that he promoted, Pico

writes in his oration On the Dignity of Man, “It is really the magic of the Asclepius that I am

talking about, and I glory in Man the Magus as described by Hermes Trismegistus.”64 What

can Man the Magus do? He says, “The Magus the earth to heaven, that is to say the force of

inferior things to the gifts and properties of supernal things.” Indeed, Pico begins this oration

with the words of Hermes Trismegistus to Asclepius, “The Magus, oh Asclepi, is a miraculous

man.”

The other kind of Neoplatonism, and operations

It is at the point of Pico’s work that we have reached the Neoplatonic age. It is in this sense

that Neoplatonism is used in this thesis. It encompasses a confluence of ideas and

philosophies. Some might call the Pico era the Neoplatonic humanist Renaissance par

excellence at whose heart of which we find Hermes Trismegistus. The fact that we find

Hermes at the heart of that era raises warning bells about whether the Renaissance was in fact

Christian or even humanist. Thanks go to Yates for pointing this out.65 Ultimately, it was

about the power of humans acting individually and, later, in concert. Rather than Christian,

perhaps it was Hermetist with a Christian sheen. It was as pantheist as it was humanist, with

humans playing a special role in the matrix of the natural universe since humans could

understand, imitate and thence manipulate and bend the power of nature to the collective will

of humans.

The entire current of “magic” led into the domain of “operations” as Yates calls it or the post-

Renaissance idea of Man consciously intervening in the physical universe to change it or

amend it for Man’s benefit or for Man’s beneficial ends. An intermediate kind of magic which

Yates refers to as “astral magic” is unmistakeably tending towards operations. It seeks “escape

from astrological determinism by gaining power over the stars, guiding their influences the

direction the operator desires.”66 Walker explains Ficino’s theory that is Stoic in origin of a

spiritus mundi (“cosmic spirit”) which provides a channel of influence between planets and

stars, and the world in which humans live. Methods of influencing the stars and planets were

detailed by Ficino.67

63 Láng, B. Unlocked Books: Manuscripts of Learned Magic in the Medieval Libraries of Central Europe Penn

State Press 2008, pp.41-42 64 Ibid., pp.90-91 65 Yates 2009, p.185 n.25 66 Ibid., p.60 67 Ficino “De Vita coelitùs comparanda” in Opera Omnia Basileae 1576 p.493, as analysed and discussed in

Walker, D.P. Spiritual and Demonic Magic: From Ficino to Campanella University of Notre Dame Press,

Notre Dame and London 1975 (first published by the Warburg Institute, University of London 1958), pp.12-

15

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In 1510, Henry Cornelius Agrippa wrote his De occulta philosophia which he published in

1533. In fact, this work was a survey of renaissance magic including Natural Magic which

was the subject of Book I.

Agrippa did the same as Ficino did in the sense of explaining methods for influencing the

stars. However, while Ficino tries to force his magic in to a Christian framework, Agrippa

does not.68 Rather, arguing the converse, Agrippa says explains that some Christian practices

including prayer itself were forms of magic, some of which were legitimate and effective. Of

these, some were effective in their own right while others were effective in influencing people

and, though people, events, but only because people were emotionally affected by the rituals

and practices.

While the perception of the cosmic order of the Agrippan Magus is almost identical to the

medieval perception, Man has now changed and so also has Man’s role in the cosmic order.

Man is “no longer the pious spectator of God’s wonders in the creation, and the worshipper of

God himself above the creation.”69 Man is now an “operator” who “seeks to draw power from

the divine and natural order.”70 In an image by Robert Fludd of Man’s Art is shown as a

monkey which imitates Nature.71 The apparent loss in dignity is more than exceeded by the

gain in power by “becoming the clever ape of nature, who has found the way nature works

and by imitating it, has obtained her powers.”72 Man has “learned how to use the chain linking

earth to heaven.”73

Contemporaneously with Agrippa, John Dee had his career as perhaps the consummate

Renaissance Magus. Dee was interested in the applied sciences, and built devices such as a

flying crab for a college stage play.74 He was certainly a mathematician as far as was possible

in the 16th Century, having written the preface to the first English translation of Euclid, by

Billingsley.75 The book included pop-up figures of 3D geometry.76

Nearly a century after Agrippa, Tommaso Campanella wrote Magia e Grazia which is mostly

on religious magic. Perhaps this is one of the reasons why Campanella was imprisoned in

68 Walker, D.P. Spiritual and Demonic Magic: From Ficino to Campanella University of Notre Dame Press,

Notre Dame and London 1975 (first published by the Warburg Institute, University of London 1958), p.93 69 Ibid., p.144 70 Ibid. 71 It is on the cover of Fludd’s Tratactus secundus de naturae simia seu technica macrocosm historia “Second

Treatise on the Imitation of Nature or the Technical History of the Macrocosm” published in 1618 with the

ape sitting in the middle of a circle depicting the sciences and engineering, including music, building

construction, surveying and geography. It is also in Utriusque cosmi historia “The history of both worlds”

published between 1617 and 1621 in which the ape is sitting on top of the world again in the centre of the

arts and sciences, but above the ape a woman is standing atop the world clearly with spiritual power with her

wrist chained to heaven above. The image is given the title “Integra naturae” or “Integration of nature”. Both

works were first published by Theodore de Bry in Oppenheim. 72 Yates 1964, pp.58, 145 73 Ibid. 74 Ibid., p.148, n.2 with primary sources Smith, C.F. John Dee London 1909 and Calder, I.R.F. John Dee, studied

as an English Neoplatonist unpublished Ph.D. thesis London University 1952 75 Billingsley, H. (trans.) Euclid The Elements of Geometrie London 1570, reprinted by Ann Arbor 1967 76 Franklin, J. “Diagrammatic reasoning and modelling in the imagination: the secret weapons of the Scientific

Revolution” in Freeland, G. and Corones, A. (eds.) 1543 and All That: Image and Word, Change and

Continuity in the Proto-Scientific Revolution Dordrecht 1999, p.82

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Rome by the Inquisition for twenty-five years suffering both torture and solitary

confinement.77 In Magia e Grazia, Campanella classifies different kinds of magic one of

which he calls “real artificial magic”. He enumerates examples such as when “Architas [sic]

made a flying dove of wood” or “when Daedalus made statues which moved through the

action of weights or of mercury” or “to make a head which speaks with a human voice”.78

Dampening the enthusiasm of those engaged in artificial intelligence in today’s computer

science, Campanella also writes, “But such forces and materials can never be such as to

capture a human soul.”

We have attempted to show how Neoplatonism and the magic talked about – if softly – during

the Neoplatonic age led to the rise of mechanical devices which are not far from the art of

invention, engineering and the age of mechanisation. This is one point where Leibniz enters

our story, as he shall do in the next chapter.

The Greeks as operators

Yates contrasts the operational role of Man with the Greek position. Yates argues that the

Greeks were not particularly interested in operations:79

The Greeks with their first class mathematical and scientific brains made many

discoveries in mechanics and other applied sciences but they never took whole-

heartedly, with all their powers, the momentous step which western man took at the

beginning of the modern period of crossing the bridge between the theoretical and the

practical, of going all out to apply knowledge to produce operations. Why was this? It

was basically a matter of the will. Fundamentally, the Greeks did not want to operate.

They regarded operations as base and mechanical, a degeneration from the only

occupation worthy of the dignity of man, pure rational and philosophical speculation.

The Middle Ages carried on this attitude in the form that theology is the crown of

philosophy and the true end of man is contemplation; any wish to operate can only be

inspired by the devil. Quite apart from the question of whether Renaissance magic

could, or could not, lead on to genuinely scientific procedures, the real function of the

Renaissance Magus in relation to the modern period (or so I see it) is that he changed

the will. It was now dignified and important for man to operate; it was also religious

and not contrary to the will of God that man, the great miracle, should exert his

powers. It was this basic psychological reorientation towards a direction of the will

which was neither Greek nor mediaeval in spirit, which made all the difference.

[emphasis in original]

Even Zeno the putative founder of the Stoics saw the aim of attaining full understanding of

the universe as a self-governing system was to “rise to complete wisdom and attain perfect

77 White, M. The Pope and the Heretic: The true story of Giordano Bruno, the Man Who Dared to Defy the

Roman Inquisition Harper Collins 2001, p.158 78 Amerio, R. (ed.) Magia e grazia Fratelli Bocca, Rome 1957, p.180 79 Yates 1964, pp.155-156

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ethical conduct.”80 At least per Cicero’s interpretation of Zeno’s doctrine – according to Hunt

– there was an element of stasis in the Stoic doctrine and conception of the universe which

might have tended away from operations. Surprisingly, it may be in the domain of what is

called magic that we see the earliest signs of the orientation towards operations in any culture.

On the other hand, an argument for the operational Greeks can be put. Greeks such as

Archytas of Tarentum (400-350 BCE) and Archimedes of Syracuse (c.287-212 BCE) were

impressive as inventors, and these two are that we know about which readily come to mind.

Could it have been that the Greeks were so beset by war from the Persians and Romans,

and/or distracted by foolish policy such as that which led to the Peloponnesian Wars, to

achieve their potential in operations?

A modern parallel can be drawn. Consider the once highly “operational” USA with the Apollo

landing, plans for the colonisation of Mars and dam-building projects on a grand scale.

Contrast that history with the veering of American policy away from operations from the

Vietnam War onwards.

It is has been written that Archimedes preferred contemplation in abstract geometry to

inventing machines and was only compelled to invent machines by his monarch, King Hero,

to defend Syracuse against the Roman army led by Marcellus (214-212 BCE) during the

Second Punic War. Nonetheless, for every potential operator like Archimedes who had to be

imposed upon to engage in operations, there might have been ten who were able and who

preferred to operate rather than to meditate. Arguably, had the Greek civilisation not been

prevented from flourishing by institutions such as the Persian and Roman Empires, then they

would have realised and expressed an intention to “operate”.

This leads to a discussion of nations or “the state” as operator, Magus or magician

commandeering the capabilities of entire populations for operations in grand projects.81

Further discussion on this topic is beyond the scope of this thesis, though the topic is worthy

of further effort.

Mathematics in operations

The related current also intertwined with magic but also running in to the ocean of “Man as

operator” is number or mathematics. Many of those who took “magic” seriously as a means

whereby Man may “operate” also took mathematics seriously. Indeed, inventors from

Archytas of Athens to Archimedes of Syracuse to John Dee of England to Huygens and

Leibniz were equally well-known for their contribution to mathematics.

80 Hunt, H. A. K. A physical interpretation of the universe: the doctrines of Zeno the Stoic Melbourne University

Press 1976, p.20 81 Couliano, I.P. translated by Cook, M. Eros and Magic in the Renaissance University of Chicago Press,

Chicago and London 1987, p.105. However, the premise of Couliano’s discussion is the as magician in the

sense of controlling education, religion and every other aspect of the lives of citizens to ensure uniformity.

Couliano does not consider that such uniformity may merely be a by-product of the organisation needed for

operations via grand projects of the kind described in the text above.

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Johannes Trithemius, Abbott of Sponheim, was a friend and teacher of Agrippa. Trithemius’

book the “Steganographia” was printed in 1606. It is a tract about cryptography and Cabalist

angel magic. It presents methods for summoning networks of angels to enable the

transmission of messages using telepathy. Part of the process of summoning these angels

involved many pages of calculations involving the numbers that represented the angels.82

It is consistent with the central role of number in the discipline of magic that Ficino includes

Pythagoras amongst the prisci magi given the mathematical achievements of the

Pythagoreans. Pico’s 900 theses include fourteen that, according to Pico, followed from the

mathematics of Pythagoras. Yates concludes that “Renaissance magic was turning towards

number as a possible key to operations”83 meaning, in our language, that without mathematics

there would be no science or engineering.

Leibniz is famous for his contribution in creating the infinitesimal calculus. The relevance to

this chapter is that Leibniz’s calculus was part of his larger vision for a Characteristica

Universalis which would be a language that serves not only for numerical calculation but for

reasoning in general.

Ramón Lull (1232/5 – 1316) sought a language with which truths could be communicated to

infidels who did not know Latin and with illiterates who knew no written language. Lull

considered such questions as how many anagrams could be formed from a finite alphabet. For

example, there are n! permutations of n letters. Lull called it the ars combinatoria or “art of

combinations” which 400 years later became one of Leibniz’s first sources.84 In 1660, Leibniz

wrote his Dissertatio de arte combinatoria which used concepts from Lull.85 Eco explains that

aside from Leibniz’s vision for a universal characteristic, his ars combinatoria had a great deal

in common with the many project for universal language undertaken over centuries up to

Leibniz’s career. However, Leibniz’s search for a characteristic emphatically was not a search

for a universal language any more than the infinitesimal calculus can be used for day-to-day

communication. Peckhaus asks the question whether Leibniz envisioned a universal language

for reasoning or a universal characteristic.86

Leibniz thought about what would be the best way of providing a list of primitives and

ultimately an alphabet of thoughts. Leibniz described an encyclopaedia as an inventory of

human knowledge which might provide the basic material for the art of combination. Leibniz

wrote that the greatest aid for the mind could be to discover a small set of thoughts from

which an infinity of other thoughts might issue in order, just as the symbols for all numbers

are obtained from the symbols 0-9.87

82 Yates 1964, p.145 83 Ibid., p.146 84 Eco, U. The search for the perfect language Blackwell 1995, p.272 85 Gerhardt, C.I. (ed.) Die philosophischen Schriften von Gottfried Wilhelm Leibniz 7 vols., 1875-1890. reprinted

by Georg Olms, Hildesheim 1978, volume IV, pp.27-102 86 Peckhaus, V. “Calculus Ratiocinator Versus Characteristica Universalis? The Two Traditions in Logic,

Revisited” History and Philosophy of Logic 2004 Vol.25, No.1, pp.3-14 87 Eco, U. 1995, p.275. Eco’s source is Leibniz’s Elementa in Couturat, L. Opuscules et Fragments Inedits de

Leibniz: Extraits des manuscrits de la Bibliothèque royale de Hanovre F.Alcan, Paris 1903, reprinted George

Olms, Hildesheim 1961, pp.42-92

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Leibniz’s work in this area was a continuation of a long line of philosophers and philologists

who had dreams akin to those of Leibniz of finding a tool for human thought in the form of

language. We do not wish to paraphrase the comprehensive work of Eco but merely to provide

some signposts.

Symbols

Symbols that putatively had a magical purpose were also used in the art of memory with only

the pragmatic purpose of assisting in memory. Certain symbols stood out for their magical

purpose and also because they were striking as well as forbidden and, therefore, memorable.

Bruno is of course the standout figure among these. Ficino is not a good example because,

unlike Bruno, he actually believed in the magical power of the images.88 Such images were

regarded by the clergy as demonic whether officially or otherwise. Augustine had already

banned the Egyptian gods whether presented as gods or recast in modern costume.89

The art of memory was not only about memory but about thought. Similarly, Leibniz’s

encyclopaedia project was about recording knowledge, but it could only be useful if

undertaken in tandem with a scientia generalis or “general science” from which the whole

encyclopaedia could be derived.90 Leibniz equated the scientia generalis with the scientia

felicitatis or the search for wisdom.91 A tool for this science was the Leibniz proposed a

battery of related and indispensable disciplines such as created about creating it with the aid

of a tool for reasoning which he called the “universal characteristic” about which more below.

Leibniz’s programme had some similarity to George Dalgarno’s bifurcated project for a

universal language, culminating in his Ars signorum of 1661. Eco says that Leibniz was

“perhaps the only scholar who considered Dalgarno respectfully”.92 For Dalgarno, a universal

language had first to accommodate the plane of content, that is, a classification of all

knowledge. Second, it required an expression level or a grammar to denote the content.93 John

Wilkins ran a similar project on behalf of the Royal Society which started in 1668. Eco’s

assessment is that while Wilkins “accomplished what Dalgarno only promised to do”,

Wilkins’ achievement was limited to an image of the universe “designed by the Oxonian

culture of his time.”94

Bruno’s memory methods converged with his pitch into the quest for the perfect language

which was at one time thought to be the language of Adam. The perfect language was

believed to allow metaphysical and scientific secrets to be unlocked. Bruno thought that the

88 Yates 1964, pp.56-57 89 Ibid., p.57, second paragraph 90 Leibniz, G.W. “Studia Felicitatem Dirigenda” winter 1678/9 in Academy of Sciences of Berlin (ed.) Sämtliche

Schriften und Briefe Series VI Philosophische Schriften, no. 4 pp.137-138 as quoted and translated in

Antognazza, M.R. Leibniz: An intellectual biography Cambridge University Press 2009, p.237 91 These ideas on the Leibnizian orientation are from Antognazza, M.R. Leibniz: An intellectual biography

Cambridge University Press 2009, pp.237-238 92 Eco, U. The search for the perfect language Blackwell 1995, p.229 93 Ibid. 94 Ibid., p.239

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hieroglyphic language of the Egyptians was superior to the alphabetic languages. This is

contrasted with Leibniz who thought that alphabetic language were superior to pictographic

languages like Mandarin because one need not be highly educated to know and alphabetical

language but need only learn the 26 or so letters to get started. No doubt, Bruno’s knowledge

of the usefulness of symbols as markers that are pregnant with meaning and his active use of

them to great effect in his memory techniques was to Bruno a provable demonstration of the

power of symbols. Moreover, Yates says that Bruno was steeped in understanding and belief

in the magical power of certain symbols. To the extent that this is correct, the magical power

of symbols will have added a new raft of power to symbols for Bruno. Leibniz’s argument

makes sense as far as getting started in a language is concerned, but moving past the

rudiments one does need a certain amount of education to understand the meaning associated

with words beyond a minimal vocabulary. In Bruno’s defence, a well-formed symbol can

convey meaning even to an illiterate person. Further, if symbols are formed in a sensible and

intuitive way, then someone trained in the rudiments of a symbolic language should be able to

make some sense of “advanced” symbols even without advanced training.

Plotinus and Iamblichus seem to imply that they too, like Bruno, prefer the hieroglyphic

language of the Egyptians.95 The search for the best language to aid the process of revelation

or as an aid to uncovering metaphysical truths “the perfect language” was on. Those who

studied the art of memory along with occult symbology with or without magical content were

also involved the search for the perfect language. The study of the accessibility of symbolic

versus alphabetic languages is another topic that is beyond the scope of this thesis but worthy

of further study.96

As explained above, the “magical” disciplines led into the domain of “operations” as Yates

calls it or the post-Renaissance ideas of Man consciously intervening in the physical universe

through science and engineering. This current in magic was really magic minus mysticism

and minus occultism. The search for the universal characteristic was part of this. That is,

rather than symbolism with occult meaning and purpose, the idea was a structure of symbols –

indeed, a language – that would not only be an aid to reasoning or to rational thought, but that

would in effect as a gateway to reason. For a moment, consider Reason as an abstract body of

“correct answers” or “Leibnizian ideas” provided. The right answers would be calculated by

the universal characteristic, or – more correctly – would be forced out by the relationship of

the structure and design of the language to Reason. The imperative “let us calculate” using

Leibniz’s envisioned characteristic was more a charge to sit down and use the characteristic to

obtain the correct answer.97 The reason was built into the system, whereas “calculating” using

the system was relatively mechanical; one would merely “crank the handle” to get the answer

out. This would not be a stretch for Leibniz since he developed and designed a mechanical

calculating machine that was eventually built. Leibniz certainly did not think that such

automatic calculation methods had to be restricted to questions involving numbers.

95 Eco, U. The search for the perfect language Blackwell 1995, pp.144-145 96 For an introduction and historical overview of this domain, see Franklin, J. “Diagrammatic reasoning and

modelling in the imagination: the secret weapons of the Scientific Revolution” in Freeland, G. and Corones,

A. (eds.) 1543 and All That: Image and Word, Change and Continuity in the Proto-Scientific Revolution

Dordrecht 1999, pp.53-115 and Eco, U. The search for the perfect language Blackwell 1995. 97 Eco, U. The search for the perfect language Blackwell 1995, p.277

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Franklin gives an overview more specific to diagrammatic reasoning.98 It may be that the

universal characteristic would be a diagrammatic language. Frege’s work towards Leibniz’s

vision is for a diagrammatic language.99 Category theory also uses diagrams, but is only

intended to apply to specifically to algebra.

Conclusion

To conclude, Neoplatonism largely encompasses what is discussed above regarding symbols,

magic and Egyptian thought. The last item largely means Hermetism, Platonism itself, and

more. Proto-science grew out of Neoplatonism, from which science grew shaking off its

mystical magical roots while certain aspects of its roots remained such as the interest in

language and the desire to create the best possible language or characteristic that aids

reasoning and acts as a gateway to propositions concerning theology, metaphysics and science

that are correct. This is about acquiring the ability to discover a principle before the effect of

that principle has been discovered or observed. This is in effect the idea of an a priori

approach to science. Further to that approach, tools of thought aid purposeful creative thought

and structured reasoning. Many will disagree with an attempt to encapsulate Neoplatonic

revolution in a single sentence. However, it is arguable that the many currents which meet in

Neoplatonism effected recognition of the goal, purpose and capability of humanity to

influence, affect, build in, improve and – indeed – control the physical universe. That is, to

“operate”.

98 Franklin, J. “Diagrammatic reasoning and modelling in the imagination: the secret weapons of the Scientific

Revolution” in Freeland, G. and Corones, A. (eds.) 1543 and All That: Image and Word, Change and

Continuity in the Proto-Scientific Revolution Dordrecht 1999, p.82 99 Smith, B. Characteristica Universalis in K. Mulligan, ed., Language, Truth and Ontology (Philosophical

Studies Series) Kluwer, Dordrecht/Boston/Lancaster 1990, pp.50–81

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Chapter 3: Ushering in modernity

Introduction

Leibniz appears at the tail-end of the Renaissance, born shortly before the end of the Thirty

Years War which was concluded with the 1648 Peace of Westphalia. The Thirty Years War

was not an historically isolated eruption. Bloodshed fuelled by misguided religious passion

marred much of the 16th Century. That the senseless slaughter above all else required a

revolutionary change in thinking had already been noticed by one born nearly one hundred

years before Leibniz, named Giordano Bruno whom we met in the previous chapter. As

Michael White wrote, “The Wars of Religion provided a harsh backdrop to Bruno’s entire

adult life and added further turmoil to the usual privations and struggles of sixteenth-century

common folk. Wherever Bruno travelled within Europe, doctrinal intolerance and endemic

slaughter in the name of God reassured him that only a spiritual and intellectual revolution

could ever disassociate religion from murder, horror, and endless pain.”100

Moving into the 17th Century, the Thirty Years War and the peace which ensued affected

intellectual circles, which included Leibniz’s teachers. In particular, it was apparent that an

intellectual order was needed which would ensure tolerance and an enduring peace. This

certainly affected the philosophical and political outlook of Jakob Thomasius (1622-1684)

the jurist, historian and philosopher whom Leibniz says is “the most celebrated German

Peripatetic”.101 Indeed, Thomasius was known as an important conciliator.102 Thomasius is

particularly relevant because Leibniz was taught and mentored by Thomasius from when

Leibniz entered the University of Leipzig at the age of 14. The need to conciliate recurs so

frequently in Leibniz’s writings that Christia Mercer coined the phrase “conciliatory

eclecticism” to describe one of the main drivers of Leibniz’s philosophy.103 In a letter to

Thomasius in April 1669, Leibniz explained that the Aristotelian and the mechanical

philosophies could be reconciled, and suggested a conception of substance to this end.

Averroism was growing in strength. Leibniz was a reader of classical Greek texts in his youth,

and also read medieval writers and Renaissance Humanists.

European-centred civilisation was extending its knowledge of the world beyond Europe.

Columbus had landed in the New World 150 years before and the Republic of Letters had

access to educated persons far beyond Europe. Leibniz was a diplomat by profession. He had

international influence, and corresponded with leaders and men of letters across Europe and

100 White, M. The Pope and the Heretic: The true story of Giordano Bruno, the Man Who Dared to Defy the

Roman Inquisition Harper Collins 2001, p.29 101 Mercer, C. “Leibniz and His Master: The Correspondence with Jakob Thomasiu” Chapter 2 in Lodge, P. ed.

Leibniz and his Correspondents CUP 2004 102 Sturm, J.C. Philosophia eclectica Altdorf, 1686, pp.72-73 Jolley writes, “Sturm’s works were widely read.

Leibniz refers to them throughout his life, although he does not refer specifically to Philosophia eclectica.”

Jolley, N. The Cambridge Companion to Leibniz CUP 1995, p.116 103 Mercer, C. Leibniz’s Metaphysics: Its Origins and Development Cambridge University Press: Cambridge,

2001, Chapter 1, pp.23ff, and Mercer, C. “The Platonism at the Core of Leibniz’s Philosophy” Chapter 15 in

Studies on Platonism and Early Modern Philosophy in the series Hutton, S. ed. International Archives of the

History of Ideas Springer Volume 196, 2007, pp.225ff

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Eurasia, and in China.104 That Leibniz corresponded with Peter the Great is not surprising

considering that a month after Leibniz met Peter the Great, Leibniz in 1712 was appointed by

Peter to the Russian Justizrat.105 Leibniz was in such frequent correspondence with Jesuits in

China that he wrote in a letter to Princess Sophia Charlotte to whom he was close in 1697, “I

will thus have a sign placed at my door, with these words: bureau of address for China,

because everyone knows that one has only address me in order to learn some news.”106

Science had recently made strides through Kepler and Galileo. Galileo was affected by the

Reason-oriented mould of Kepler and the empirico-deductive mould of Averroism. With the

success of Galileo and the influence of his patron Paolo Sarpi, who was Atheist and an

Averroist, the empirico-deductive approach to science was being promoted in opposition to

Kepler’s Reason-oriented approach which was also represented by Leibniz’s second (after

Jakob Thomasius) mentor Christian Huygens. Invention of machinery was burgeoning in

Leibniz’s day, and Leibniz took an active interest in the design and building of machines.

We see that while Leibniz never announced his scientific programme, he drip fed it over his

career and developed his method over his career.107 While his mathematics and physics were

developed over time, the seeds of certain aspects of Leibniz’s metaphysics such as the

doctrine of the best of all possible worlds and the principle of sufficient reason were present

in his earliest writings. Arguably, those earliest ideas were animated by Leibniz’s passion to

advance humanity by pursuing knowledge. Since Leibniz was born into “the century of

genius”,108 the seventeenth century, he found many debates and programmes to contribute to

as well as starting a few of his own. If one is looking for a declaration of Leibniz’s scientific

agenda, it is set forth most cohesively in summary form in his letters.

While the empirico-deductive approach was rising on the Continent and in Britain, Leibniz

was a torch-bearer for the Keplerian approach to science. Continental Platonism was imbued

with science, and scientific discovery was its central concern. Their definition of the

Discovery process is part of their definition of the relationship between God, Man and the

physical universe, which is not reconcilable with empirico-deductivism.

104 Cook, D. J. and Rosemont, H. Jr. (trans.), Leibniz, G. W. Writings on China Open Court Publishing Company,

Chicago and La Salle, Illinois 1994 accessed at

http://www.strongwindpress.com/word/TuiJian/LeibnizWritings%20on%20China.doc on 29 Apr 2011 105 Smith, J. E. H. An archive of philosophy news, notes, and academic work in progress

http://www.jehsmith.com/philosophy/2009/01/peter-the-greats-decree-appointing-leibniz-to-the-russian-

justizrat.html accessed 26 Feb 2012 106 Perkins, F. Leibniz and China: a commerce of light Cambridge University Press 2004, p.115. Also see pp.113-

115. 107 See Mercer and Antognazza’s detailed diachronic studies of Leibniz’s development. Mercer focusses on

Leibniz’s metaphysics while Antognazza traces Leibniz’s overall intellectual development including his

professional responsibilities as a diplomat. Mercer, C. Leibniz’s Metaphysics: Its Origins and Development

CUP 2001 and Antognazza, M.R. Leibniz: An Intellectual Biography CUP 2008 108 Koyré, A. Newtonian Studies Chapman & Hall, London 1965, p.53

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Leibniz’s relationship to modernity

Popularly, modernity encompasses a lessening of importance of forms of tradition, and

increasing importance of new abstractions such as nation states and corporations.109 The

popularly promoted idea of modernity encompasses capitalism, industrialisation, the nation

state, scientific experiment, secularization and rationalization.110 The Thirty Years War which

ended two years after Leibniz was born is regarded as being at the beginning of modernity.111

This might be because it ushered in the Westphalian system of nation states with the 1648

Treaty of Westphalia.

Modernity is also regarded as encompassing rationality, an absence of excessive religiosity,

the use of logical deduction and reliance on precision in taking observations especially with

sensitive instrumentation. Leibniz promoted all of these things. He also promoted industry,

science, the nation state and rationality. At the same time, he recognised the Neoplatonic roots

of science. However, he was no alchemist or magician. Leibniz was motivated by the power

of rationality when applied to pragmatic scientific and industrial operations. He saw even

greater power in the application of lucid rationality to metaphysics and philosophy, because it

is in these intellectual acts that the largest questions that trouble humans can be dealt with

thereby allowing great leaps in science, thence in industry and thence in the human condition.

The rise of modernity saw a decline in the sway of religious fundamentalism and this went

hand-in-hand with the rise in the use of and high regard for rational thought. This does not

mean that people believed in God any less. Rather, what changed was the conception of God.

The rising conception of God was of a rational God whose every act is for good reason.

Leibniz tirelessly promoted the idea that the universe is the best possible universe, because it

was made by a Creator who designed it so that it would unfold in the best possible way.

Laws that function without divine intervention

Leibniz believed that God acted through objective laws to create the universe, and these

objective laws can be understood whereby the universe is accessible to human understanding

and modification. In criticism of the philosophers Scaliger, Sennert and Sperling, Leibniz

wrote to his former teacher Thomasius, “…they conclude that God produces creatures rather

from his own active power than from the objective and, so to speak, passive power of nothing.

In their opinion, therefore, God produces things out of Himself and is thus the primary matter

of things. But you will judge more correctly on this subject.”112

109 Hooker, R. “World Civilizations” http://www.wsu.edu/~dee/GLOSSARY/MODERN.HTM Washington State

University 1996, accessed on 7 August 2010 110 Barker, C. Cultural Studies: Theory and Practice SAGE Publications, London 2008 pp.188ff and pp.211-212 111 University of Sydney Library http://www.library.usyd.edu.au/libraries/rare/modernity/ accessed on 7 August

2010 112 Loemker, p.94 first paragraph (Letter to Thomasius, April 20/30, 1669). In this, Leibniz at least approximates

Hermes Trismegistus, “…god [sic] is father of the cosmos, but the cosmos is the father of the things in the

cosmos; the cosmos is the son of god, and the things in the cosmos are made by the cosmos.” Corpus

Hermeticum XI §8 in Copenhaver, B.P. Hermetica Cambridge University Press 1992, p.29

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In his “Discourse on metaphysics” of 1686, Leibniz writes, “when we say that things are not

good by any rule of excellence but solely by the will of God, we unknowingly destroy, I think,

all the love of God and all his glory. For why praise him for what he has done if he would be

equally praiseworthy in doing exactly the opposite?” Rather, “the eternal truths of

metaphysics and geometry, and consequently also the rules of goodness, justice, and

perfection” are the consequences of God’s understanding rather than of his will, and God’s

understanding does not depend upon his will.113 Essentially, geometry and harmony are

beautiful in themselves not because God has chosen them and, moreover, God chose them as

they are because of his perfect understanding.

Hylarchic principle

Leibniz’s opposition to Henry More’s hylarchic animism includes, among other arguments,

that the idea is superfluous,114 is not distinctly conceived and leaves many things to be

explained unlike the commonly believed notion of individual souls.115 Leibniz says that space

is not a real absolute being and is certainly not God himself. Moreover, since space has parts,

it does not belong to God. Leibniz then says that space is merely relative as time is, and that it

is merely an order of coexistences as time is an order of successions.116

Newton expresses a kind of hylarchic animism similar to Henry More’s. By contrast, Leibniz

has said that God is not in the universe and the universe exists independently of God. Newton,

on the other hand, writes that God is omnipresent, not only virtually but substantially. Newton

says that God constitutes space and time. Leibniz says that space and time do not even exist,

but are creations of the human mind.117 Of God, Newton writes, “He endures for ever, and is

everywhere present; and by existing always and everywhere, he constitutes duration and

space. … He is omnipresent, not virtually only, but also substantially, for virtue cannot subsist

without substance. In him are all things contained and moved; yet neither affects the other:

God suffers nothing from the motion of bodies; bodies find no resistance from the

omnipresence of God.”118 Of course, Newton is self-contradictory because he also posits a

mechanical clockwork universe,119 and Leibniz disagrees with this side of Newton too:120

113 Loemker, p.304 114 Leibniz, G.W. 1698 in Wiener, pp.138-9 115 Leibniz, G.W. “Reflections on the doctrine of a single universal spirit” 1702 in Loemker, , pp.554-560 116 Wiener, p.223 §3; also see Leibniz’s response to Dr Clarke’s second letter, pp.222-228 117 Incidentally, the concept that space is infinite is core to Henry More’s conflating God with space. More is

quoted saying this many times in Koyré, A. From the Closed World to the Infinite Universe Harper and

Brothers, New York 1957. See Chapter 6 “God and Space, Spirit and Matter” pp.125-154. By contrast,

Leibniz does not think that the universe is infinite. 118 General Scholium in the 1713 (second) edition of Principia II, 311ff quoted in Burtt, E.A. 1932 2nd ed,

reprinted 1950, p.257. Burtt suggests that Newton added the General Scholium to counter the disapprobation

from the Godlessness of the pure positivism and empiricism of the first edition of the Principia. Was the

General Scholium a populist sop to the churchgoing masses? The General Scholium appears to be

irreconcilable with the positivism and empiricism of the Principia. In any case, even considering each

outlook on its own, neither is supportable. 119 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, p.256 120 Leibniz, G.W. Letter to Samuel Clark November 1715 §4 Wiener, p.216

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Sir Isaac Newton, and his followers, have also a very odd opinion concerning the work

of God. According to their doctrine, God Almighty needs to wind up his watch from

time to time: otherwise it would cease to move. He had not, it seems, sufficient

foresight to make it a perpetual motion. Nay, the machine of God’s making is so

imperfect, according to these gentlemen, that he is obliged to clean it now and then by

an extraordinary concourse, and even to mend it, as a clockmaker mends his work…

The idea that God acts through objective laws is fundamental to modernity, and a defining

feature of it. The objective action of God’s mind through universal principles that are

discoverable by human minds makes the universe the legitimate and natural locus of proactive

intervention, change and improvement by humans. This marks the onset of modernity. Of

course machines (modes of mechanised work and transport) and increasingly powerful energy

sources are media for such human proactive action.

Modernity and discoveries achieved by reason

Modernity often refers to lifestyle or amenities of modern life being made available to as wide

a section of the population as possible. It can also mean a departure from superstition and

religious fundamentalism, and an embrace of rationality. This implies the ability to answer

questions using a thought process rather than dogma, which is a rather Platonic-dialogue

oriented technique. It is a rational process whose pursuit is open to any human mind, and that

process can lead if not to a final answer then at least to greater clarity and an incomplete

answer. Leibniz took this further with his quest for a Universal Characteristic which would

allow questions to be answered using a calculating procedure. This, however, was distinct

from the “art of discovery”.121 The Universal Characteristic would make a process of

reasoning available to all people who had a basic education and were armed with pen and

paper.122 It would be a calculus which depends on the analysis of ideas, and which is more

important than the calculi of arithmetic and geometry. He says, “its formation seems to me

one of the most important things that can be undertaken.”123,124

To a 21st Century mind, the idea that the earth revolves around the Sun rather than vice-versa

seems a “modern” one. However, what is perhaps the feature that more powerfully gives it the

distinction of “modern-ness” is the fact that a human mind discovered it through reasoning

and by considering the paradoxes in the previously prevailing belief system. Praise for this

goes to Kepler. However, one of the most salient features of Kepler’s reasoning is hypothesis.

121 Leibniz, G.W. c.1693 in Wiener, , pp. 77-80 122 Leibniz, G.W. 1677, Ibid., pp.23-24 123 Leibniz’s final words in “Response to Bayle’s Dictionary article Rorarius” 1702, Loemker, p.585 124 Richard Brown notes that Leibniz did not seem to have made much real progress towards the Universal

Characteristic. As regards stating more than has actually been delivered, “this is especially the case in his

writings on the Universal Characteristic or Lingua Philosophica. It is true that this project motivated his

unique approach to calculus and logic, which in itself is a singular achievement. Yet as far as the general

project is concerned little had been accomplished except the production of a vast amount of propaganda.

Over and over again he describes the wonderful things he expects from the Characteristic, while strongly

hinting that it is already is in his possession.” Brown, R. C. Leibniz, unpublished, Chapter 11 “Epilogue”

p.167 Judgement may be reserved, however, for there may be much more to find in the vast trove of Leibniz

manuscripts.

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Of course, Kepler was an able mathematician. Yet, fundamental to Kepler’s process of

reasoning was a presumption of harmony, the formulation of a hypothesis, and then the

undertaking to test the hypothesis and check its complete conformance with observations.

Kepler and Galileo’s outlook typified the “new mechanical philosophy”125 (“NMP”) which

was part of the development of Rationalism which is to be discussed below in Chapter 3.

Brown reports that Erhard Weigel who taught some mathematics to Leibniz at the University

of Jena shared with Leibniz a desire to reconcile Christianity, Aristotle and the NMP. While

Weigel regarded the NMP of Kepler, Galileo and such like as an extension of Aristotle,126 we

will later argue that Rationalism is better regarded as an evolution out of Neoplatonism rather

than as an extension of Aristotle.

Kepler and Galileo’s outlook typified the “new mechanical philosophy”127 which developed

hand-in-hand with Rationalism, which will be discussed further in Chapter 3. Brown reports

that Erhard Weigel who taught Leibniz mathematics at the University of Jena shared with

Leibniz a desire to reconcile Christianity, Aristotle and the new mechanical philosophy.

Weigel might have seen the new mechanical philosophy of Kepler, Galileo and such like as an

extension of Aristotle. However, we will later argue that Rationalism was for the most part an

evolution of ideas from Neoplatonism.

Hypothesizing a priori

What is critical is the pre-thought that went into his hypothesis formulation; clearly, Kepler

did not pick a hypothesis “out of the air”. Kepler had metaphysical presumptions in how the

universe must be designed, and in what the Creator’s intention must have been in designing

the universe arising from his overall understanding of God, geometry, Man and Man’s place

in the universe. An interconnection between God and geometry was present in Kepler’s

thoughts, and to that he owed a debt to the Pythagoreans and Plato. What did Kepler add to

the traditions of Pythagoras and Plato? Why could Pythagoras and Plato not have completed

Kepler’s work? Perhaps they “only” lacked the observational data that Kepler had access to,

and the numerical methods work of Tycho Brahe and Kepler himself. Of course, the data and

methods involve enormous suites of resources. However, arguably, the Pythagoreans and

Plato worked with a similar metaphysical orientation and set of assumptions about the nature

of the universe to Kepler.

Leibniz recommended Kepler’s a priori method, “The most perfect method involves the

discovery of the interior constitution of bodies a priori from a contemplation of God, the

author of things. But this method is a difficult one and not to be undertaken by anyone

whatever.” Further, “Some hypotheses can satisfy so many phenomena, and so easily, that

125 A term used by Richard Brown in Brown, R. C. Leibniz, unpublished, Chapter 4 “A Young Central European

Polymath Between the Scholastics and the Moderns” p.33 126 Ibid. 127 Ibid.

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they can be taken for certain. Among other hypotheses, those are to be chosen which are the

simpler; these are to be presented, in the interim, in place of the true causes.”128

We cannot say that the ancient Greeks were not used to formulating hypotheses. Archimedes

might have done so mentally without committing it to writing. Archytas might have done so

in working out how to double the cube.129 Most of all, Plato in his dialogues makes an art and

game of proposing hypotheses for testing.130

It is clear in Leibniz’s work on the mine pump, simply through his multiple attempts, that he

must have followed a process of hypothesis testing. Similarly with Papin in his letters to

Leibniz, and his several steam engine design proposals to various persons of significance.

Leibniz was familiar with hypothesis formulation in Astronomy, perhaps directly from

reading Kepler.131

A cohesive reason-based metaphysics is associated with the foundations of modernity –

counterposed against, say, a literalist reading of religious scriptures. Such a metaphysics

provided preconceptions about the structure of the universe. The current discussion

surrounding cosmic radiation and the lack of empty space is forcing re-examination of the

foundations of physics.132 Yet Leibniz himself had much to say on the non-emptiness of

space,133 and much of it was derived from the principle of sufficient reason which emanated

from a quasi-theological position on how God necessarily must think.

128 Loemker, p.283 129 While the cube cannot be doubled with straight-edge and compass, Archytas who studied at Plato’s Academy

worked this out a solution in the 4th Century BCE. We quote Rivest, F. and Zafirov, S. “Duplication of the

cube” accessed at http://www.cs.mcgill.ca/~cs507/projects/1998/zafiroff/Duplication of the Cube.htm 27

April 2011. Archytas used “a bold construction in three dimensions, determining a certain point as the

intersection of three surfaces of revolution, (1) a right cone, (2) a cylinder, (3) a tore [sic] or anchor-ring with

inner diameter nil. The intersection of the two later surfaces gives (says Archytas) a certain curve (which is in

fact a curve of double curvature), and the point required is found as the point in which the cone meets this

curve.” (italics in original) 130 It is not confirmed whether Gauss performed the experiment on the angle sum of a large triangle by placing

fires on two distant mountains to check whether the triangle formed by the path travelled by the light had an

angle sum of 180 degrees. Mathematics Illuminated Geometries Beyond Euclid published by Annenberg

Learner §8.4 Spherical and Hyperbolic Geometry accessed at

http://www.learner.org/courses/mathilluminated/units/8/textbook/04.php 4 June 2011 131 1686, Wiener p.296 132 Shaviv, N. J. “Cosmic Ray Diffusion from the Galactic Spiral Arms, Iron Meteorites, and a Possible Climatic

Connection” Physical Review Letters 2002 Vol. 89, Iss. 5. The work of Dayton Miller casts doubt on the

negative result of the Michelson-Morley ether experiments. For an overview, see Swenson, L. S. “The

Michelson-Morley-Miller Experiments before and after 1905” Journal for the History of Astronomy Vol. 1,

p.56 accessed at http://articles.adsabs.harvard.edu//full/1970JHA.....1...56S/0000056.000.html 12 May 2011.

Also see Miller, D. “The Ether-Drift Experiment and the Determination of the Absolute Motion of the Earth”

Reviews of Modern Physics 1933 Vol. 5, Iss. 3, 203-242 in which Miller calculates an absolute cosmic motion

of the earth and of the solar system using the results of the Morley-Miller experiments 1902-1906 and

subsequent experiment at Mount Wilson 1921-1924. 133 Leibniz, G.W., White, C. (trans.) An Essay on the Causes of Celestial Motion Fusion Energy Foundation

1986, esp. pp.6-7

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Broad-based influence of reason on culture

An absence of superstition was seen in many cultures prior to extended European civilisation.

Thus, modernity cannot be defined by a lack of superstition or even by a lack of reason. Even

the modern era’s broad-based facility of reason among the populace is not definitive because

there have been entire civilisations prior to the present in which a large proportion of the

population used methods which today could be described as scientific or at least with

ingenuity, with regard to astrogation, navigation, ship-building or boat-building, fishing,

domestication of animals, etc. Thus, modernity is simply this civilisation’s manifestation of

reason/rationality. There are parts of the world in which superstition can be found even today.

However, there were, to varying degrees, parts of the world – national cultures, say – certainly

through the 19th and 20

th Centuries in which reason was dominant. Of course, on the other

hand, irrationality even exists in the Western world in the 21st Century even in professional

and social circles with a high-level of formal education.

Leibniz had something to do with the establishment of a dynamic which saw the broad-based

influence of reason on culture and the infusing of post-17th Century culture with reason.

Leibniz’s letters to national leaders, such as the Czar of Russia, indicate a concern to uplift the

minds of the population as a whole. Leibniz’s personal drive in this direction is illustrated by

Kutateladze when he describes the debt owed by Russian science to Leibniz:134

Science in Russia had started with the foundation of the Academy of Sciences and Arts

which then evolved into the Russian Academy of Sciences of these days. The turn of

the sixteenth and seventeenth centuries is a signpost of the history of the mankind, the

onset of the organized science. The time of the birth of scientific societies and

academies accompanied the revolution in the natural sciences which rested upon the

discovery of differential and integral calculus. The new language of mathematics

brought about an opportunity to make impeccably precise predictions of future events.

To the patriotism of Peter the Great and the cosmopolitanism of Leibniz we owe the

foundation of the Saint Petersburg Academy of Sciences as the center of Russian

science. Peter and Leibniz stood at the cradle of Russian science in much the same

way as Catherine I and Euler are the persons from whom we count the history of the

national mathematical school in Russia. We must also acclaim the outstanding role of

Leibniz who prepared for Peter a detailed plan of organizing academies in Russia.

Leibniz viewed Russia as a bridge for connecting Europe with China whose

Confucianism would inoculate some necessary ethical principles for bringing moral

health to Europe. Peter wanted to see Leibniz as an active organizer of the Saint

Petersburg Academy, he persuaded Leibniz in person and appointed Leibniz a

Justizrat with a lavish salary.

This is an early conception of the General Welfare of the population of a nation which was

also found in the American Declaration of Independence and Constitution. Leibniz’s New

Essays Concerning Human Understanding in response to John Locke’s Essays on Human

Understanding indicates this contention of “life, liberty and the pursuit of happiness” versus

134 Kutateladze, S. “The Mathematical Background of Lomonosov's Contribution” Journal of Applied Industrial

Mathematics, 2011, V. 5, No. 2, 155–162. Accessed at

http://www.math.nsc.ru/LBRT/g2/english/ssk/mvl_e.html 4 Dec 2011

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“life, liberty and property”.135,136 (In the next chapter, we shall meet Paolo Sarpi whose

influence Leibniz opposed. Robertson writes that “there can be no doubt” that Sarpi

“anticipated Locke in the sphere of metaphysics” and that “there is reason for thinking” that

Sarpi “supplied Locke with the germs of many of the ideas which we find expanded” in

Locke’s writings.137) In this way, Leibniz’s thought was instrumental in the creation of

national cultures which fostered the pursuit of knowledge, invention and an expanding

scientific understanding by the participation in these activities of as many members of the

population as possible. Leibniz’s idea was not only that society and nations should be

organised to promote these things but that these pursuits were the main and perhaps only

reason for the existence of society and nations, and are the end around which all political

activity and legal principles for organising people should be directed.

Conflicting ideas on the nature of Reason

Let us explore the idea that Reason and its application are at the heart of modernity. Before

doing so, a digression on what is meant by “reason” is needed. In particular, reason is

counterposed to deduction, and more will be said on the distinction in Chapter 6 “Discovery

and deduction”.

Reason as Plato exhibited it in The Republic is not logical deduction for the character Socrates

raises new points from “left field” that could not have been deduced and thereby commence

entirely new lines of enquiry and, often, confounds his interlocutors.

135 In John Locke’s Essays on Human Understanding, §18 Chapter III Book IV Volume 2, Locke exhibits a

purist positivist stance by writing, “‘Where there is no property there is no injustice,’ is a proposition as

certain as any demonstration in Euclid: for the idea of property being a right to anything, and the idea to

which the name ‘injustice’ is given being the invasion or violation of that right.” That is, without property

rights, it is not possible to do anyone any harm, because all concepts of justice arise from property. This is

opposed to confluence of Justice with Goodness in Plato’s The Republic. If we are in doubt as to Locke’s

positivist position, Locke then writes, “Again: ‘No government allows absolute liberty.’ The idea of

government being the establishment of society upon certain rules or laws which require conformity to them;

and the idea of absolute liberty being for any one to do whatever he pleases; I am as capable of being certain

of the truth of this proposition as of any in the mathematics. saying that there where is no property there can

be no injustice, just as where there is no government there is absolute liberty.” This indicates that liberty is

not the freedom to do what is good or right, but “freedom” to do what one pleases or liberty in the sense of

libertinism. The very title of Book I Volume 1 “Neither principles nor ideas are innate” is a bold positivist

statement with which any concept of happiness distinct from pleasure would find it difficult to coexist.

Project Gutenberg edition Volume 1 at http://www.gutenberg.org/cache/epub/10616/pg10616.txt and Volume

2 at http://www.gutenberg.org/cache/epub/10615/pg10615.txt accessed 7 May 2011. 136 Contrarily, Wikipedia credits John Locke with the “pursuit of happiness” part of the Declaration of

Independence. While Wikipedia may not be relevant as an academic or research source, it is a common

popular source, and are taking this opportunity to correct in a research context what is being promoted among

the public at large. See http://en.wikipedia.org/wiki/Life,_liberty_and_the_pursuit_of_happiness accessed 7

May 2011. 137 Robertson, A. Fra Paolo Sarpi: The Greatest of the Venetians George Allen & Company, London 1911,

pp.84-85

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Nicolaus of Cusa

We first introduce Cardinal Nicolaus of Cusa (1401-1464) because he revolutionized the

understanding of human reason, the pursuit of knowledge by humans, and helped define the

domain of what is knowable or in which humans seek knowledge.

Cusa was educated in a region of Germany where the Brotherhood of the Common Life was

active though possibly not in a school directly run by the Brotherhood. An overview of the

Brotherhood and its circles will help place the reader in the milieu in which Cusa worked.

The Brotherhood was a religious order founded by Gerard Groote (1340-1384). In 1374,

Groote, at the age of 34 having hitherto lived in relative luxury, experienced religious

conversion following a sickness, and entered the Carthusian monastery as a guest to

participate in their severe regimen of prayer, fasting and manual labour. Ultimately he

departed from the Carthusians but thenceforth lived an austere life of prayer, study and

preaching. Groote was from a wealthy merchant family. After his parents died as victims of

the Black Plague, he left one of the estates he inherited to the Carthusians. He ceded part of

the house in which he lived to poor women so establishing a community known as the Sisters

of the Common Life. The sisters supported themselves through agricultural and artisan

pursuits, and gained great expertise in agriculture and sewing. They built a flourishing dairy

business and earned an impressive income from sewing and knitting. Discipline and

obedience to the two matrons was expected. The Sisters became a powerful centre of Church

reform.138

Groote also established a monastery for the Brotherhood of the Common Life, which

provided superior education to capable children regardless of family background. The

Brotherhood was dedicated to educating capable children in the Greek classic and in the

Christian tradition of St Augustine. The Brotherhood ultimately established over a hundred

schools across Europe and influenced many more. The order sought to provide education

regardless of background and sought to transform the potential of the population of Europe in

the wake of the Black Plague.

Erasmus of Rotterdam also had an education heavily influenced by the Brotherhood. Erasmus

along with others created the Devotio Moderna movement which catalysed a revolution in the

Church. This “New Devotion” or “Modern Piety” ultimately swept up such personalities as

Luther, Calvin and Loyola.139 While Nicolaus of Cusa was only peripherally connected with

the Devotio Moderna,140 he played an equally important role in history.

138 Jalas, J. (ed.) Gilbert, W. Renaissance and Reformation Lawrence Books, Kansas 1997: Carrie E-Books,

1998, Chapter 9: The Northern Renaissance and the background of the Reformation accessed at

http://vlib.iue.it/carrie/texts/carrie_books/gilbert/09.html 24 Dec 2011 139 Broekhuysen, A. Gerard Groote and the Brethren of the Common Life Wisdom’s Goldenrod Center for

Philosophic Studies, Hector New York accessed at

http://wisdomsgoldenrod.org/publications/misc/gerard_groote.html 24 Dec 2011 140 Bocken, I. “The Language of the Layman: The Meaning of Imitatio Christi for a Theory of Spirituality”

Studies in Spirituality vol. 15, 2005, pp.217-249

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In 1418 the Brotherhood was charged with heresy. Jean Gerson the former chancellor of the

University of Paris defended the Brotherhood, making appeal to the Christian concept of

imago viva Dei and the duty of Christians to act in the imitation of Christ. Gerson’s further

significance is underlined by the fact that he later wrote the educational curriculum for the

young Louis, the future King Louis XI of France, with emphasis on the study of St

Augustine’s City of God. Thomas á Kempis (1380-1471) was a follower of Groote, and

expressed the ideals of the Brethren in The Imitation of Christ (c.1418-1427). Nicolaus of

Cusa’s theology has been called that of Thomas á Kempis but in philosophical language.141

The Brotherhood and its supporters were significant in the movement that supported the

independence of France. It might not be an accident that Jeanne d’Arc who was so central in

liberating France from England grew up in Domremy adjacent to German towns where the

Brotherhood was active.

Nicolaus of Cusa, usually referred to as “Cusa”, was a very significant reformer and activist

from his position within the church hierarchy. Cusa wrote the Concordata Catholica in 1433

during the Council of Basel which ultimately failed. In the Concordata, the concepts of

human rights and national sovereignty can be found in seminal form. More than 200 years

later, the concept of national sovereignty became the basis of the 1648 Treaty of Westphalia.

What is now known as the “Westphalian principle of national sovereignty” is the foundation

for international relations in the 21st Century.

Cusa was active in initiating the Council of Florence which brought together the Roman and

Eastern Orthodox Churches, and concluded in 1439. It was due to Cusa that the doctrine of

the Filioque (i.e. “and from the Son”) was agreed at the Council of Florence. This is the

doctrine that the Holy Spirit proceeds from the Father and from the Son, not only from the

Father. This ensures a greater accessibility of the Holy Spirit to humanity.

While God an infinite being created the universe, humans have access to ideas concerning the

infinite. Humans can get closer to God, and the human mind can always get a better grasp of

Creation. This is the same as the consequence of the doctrine of the Filioque, that humans are

able to come closer to God. Indeed, the Holy Spirit proceeds from the Son to reach us. The

spiritual relevance might be more obvious. However, in the intellectual and scientific sense,

the human mind can progressively come to better understand the universe, and this is nothing

but the process of scientific discovery. Cusa explained the competence of human thought for

scientific understanding even of God’s creation as a whole though his work De Docta

Ignorantia which he defended in correspondence with Johannes Wenck against attacks by

Wenck.

Most significant for this thesis, Cusa conceived the role and position of mind in relation to

Creation or the physical universe, so establishing an epistemological foundation for science.

The premise of De Docta Ignorantia is the relationship of the finite with the infinite. The

human mind is finite compared with the infinity of God. The physical universe, which is

God’s creation, is also infinite. This might not mean that the physical universe is infinite in 141 Scharpff, F.A. Der Kardinal und Bischof Nikolaus von Cusa als Reformator in Kirche, Reich und Philosophie

des fünfzehnten Jahrhunderts (“The Cardinal and Bishop Nicolaus of Cusa as Reformer in the Church,

Empire and Philosophy of the Fifteenth Century”), Tubingen 1871

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size, but in possibilities. Thus, the human mind can never fully understand the universe nor

can it fully grasp God. However, this does not mean that there is no point in trying. On the

contrary, there is every point in trying. Since a circle is like an infinite-sided polygon, a

polygon with a finite number of sides can never match it but it can get progressively closer.142

This is an analogy only, but one that is as useful as it is simple to fight back against those who

argue that humanity is condemned or destined to be passive or ineffective in a universe which

is governed by the diktat of a God who can never be understand. It is a powerful argument

against regarding God and the forces of nature as playing with human in an arbitrary or

whimsical way.

In explaining the human ability to formulate a “higher hypothesis”, the analogy of the circle is

used again. By remaining within the framework of existing thinking, we behave like a

geometer who restricts himself to a regular polygon. How can he achieve the smooth circle?

The circle is not an infinite-sided polygon but a qualitatively different object. A higher power,

so to speak. Humans have the ability to transcend the existing “system of regular polygons”

and move up to the circle thus solving the conundrum of the day, be it political, artistic, social,

cultural or – what is most relevant to this thesis – scientific.

How does one find or move to that higher hypothesis? The ability to do so is fundamental to

progress of all kinds. Thus, renaissances are typically renaissances of human thought, and

progress explodes not in one but in all domains: political, artistic, social, cultural, scientific.

Indeed, the separation between these domains is artificial, for all are refined and advanced by

the capabilities of the human mind.

Cusa might have been the first to say that inspiration is a valid source of scientific insight and,

ultimately, of new knowledge. Indeed, Cusa argued that it is the only source of new

knowledge, and he counterposed it to discursive logic. Translations of Cusa, such as Jasper

Hopkins’ translation, use “discursive reasoning” but the context makes clear that “discursive

logic” or even “deductive logic” was his meaning.143

Kepler consciously used Cusa’s prescription in formulating his hypotheses for the working of

the solar system yet we do not see inspiration in Kepler so much as an a priorist belief in

universal harmony combined with impressive rigor or discipline in his calculations.144 The

testing of the hypotheses was conducted largely mathematically. Leibniz’s method in

discovering the calculus was very different, but he was equally supportive of the use of

hypothesis. Meli defends Cassirer’s thesis of 1902, that “the legitimacy of hypotheses in

natural philosophy and mathematics was defended by Leibniz exactly as Kepler had done in

142 Grosholtz refers to “Leibniz’s infinite-sided polygon” several times Gillies (ed.) “Was Leibniz a

Mathematical Revolutionary?” pp.125, 126, 133 However, Cusa deserves credit for the concept. 143 Available online at http://jasper-hopkins.info/ Accessed 1 Jan 2010 144 Kepler wrote of Cusa others divinus mihi Cusanus, i.e. “Cusa and others seem to me divine” in drawing the

analogy of the circle compared with polygon to God compared with his creatures. Duncan, A.M. (trans.)

Kepler, J. Mysterium Cosmographicum Abaris Books, Janus Series Norwalk USA 1981, Chapter II “Outlines

of the primary derivation” p.93

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astronomy. In their philosophical systems phenomena assume a new dignity and the true

hypothesis becomes the instrument for binding them to the laws of knowledge.”145

Cusa was the first to say that the universe is infinite.146 Bruno who was born 84 years after

Cusa died also proclaimed the infinity of the universe. Fifty years after Bruno’s death, Henry

More was gripped by the idea of the infinity of the universe, not necessarily adopted from

Cusa or Bruno directly, and in particular the infinity of space. As mentioned elsewhere in this

thesis, the infinity of space inexorably led Henry More to the idea that God is in space.

Newton was in partial agreement with these conceptions of More.

Cusa’s ideas on mind gain traction in science

Kepler consciously used Cusa’s prescription in formulating his hypotheses for the working of

the solar system yet we do not see inspiration in Kepler so much as an a priorist belief in

universal harmony combined with impressive rigor in his calculations. The testing of the

hypotheses was conducted largely by calculation. Leibniz’s method in discovering the

calculus was very different.

The gaining of understanding and following it up with the potent exercise of mind on the

physical universe brings us into the domain of modernity. This certainly was not something

that had never been thought before. For example, Plotinus (3rd Century C.E.) wrote that since

Intelligence is the base of all, understanding is a prerequisite to the exercise of noös (spirit) on

söma (body).147 The gaining of understanding and following it up with the potent exercise of

noös on söma brings us into the domain of modernity. Central to modernity was insight into

and consequent control over the physical universe. Kepler’s purpose was to better understand

Creation. For a human to even consider that it was for them to understand the universe could

have been regarded as blasphemous arrogance that put him/her on the same footing as God.

Kepler’s theological justification, perhaps to keep himself out of trouble with church

authorities, was that by better understanding God’s creation we can better glorify God.148

Similarly, Leibniz wrote that “the greatest usefulness of theoretical natural science, which

deals with the causes and purposes of things, is for the perfection of the mind and the worship

of God.”149 What Kepler did not say was that scientific development contributes to the public

good, perhaps because Kepler’s work in understanding the heavens did not have a clear

pragmatic application in his time. Leibniz could see that science and engineering contribute to

the public good, and he united Kepler’s position with the public good, saying, “To contribute

to the public good and to the glory of God is the same thing.”150

145 Meli, pp.19-21 referring to Cassirer, E. Leibniz’ System in seinin wissenschaftlichen Grundlagen Marburg

1902, pp.362-3 and 503, and other places 146 Koyré, A. From the Closed World to the Infinite Universe Harper and Brothers, New York 1957 p.6 147 Mead, G.R.S. Plotinus Theosophical Society London 1895, pp.24, 26, 28 148 Duncan, A.M. (trans.) Kepler, J. Mysterium Cosmographicum Abaris Books, Janus Series Norwalk USA

1981, p.53 149 Leibniz, G.W. c.1682-4, Loemker, p.280 150 Draft of a letter by Leibniz to Thomas Burnett 1699, quoted in Antognazza, M.R. Leibniz: An intellectual

biography Cambridge University Press 2009, p.233

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Understanding principles of nature precedes surpassing or controlling nature, and the

motivation for gaining that understanding is to surpass and control nature. As mentioned in

the previous chapter, it allows us to ape nature and thence master it. That it is natural for

humankind to do so was also a consequence of the Egyptian/Hermetic conception of Man as

magus who can control even the stars. That it is humankind’s right to do so was the message

of the Renaissance bound up with Christian theology, resulting from the conception that

humanity is made in the image of the Creator.151,152 Leibniz explained, “It seems to me that

the aim of all humankind should chiefly be nothing other than the knowledge and

development of the wonders of God and that it is for this reason that God has given

humankind dominion over this globe.”153 Humanity consciously using its superior status over

all of nature is the defining characteristic of modernity and crystallises what the Renaissance

worked towards.

Speculation and contemplation, including the exercise of reason, do not on their own define

modernity. Whittaker says “the happiness involved in [the speculative life] ... is regarded as

something that necessarily goes with mere thinking and understanding” in reference to “a

self-conscious theory of [the speculative life as set forth] ... as at the opening of Aristotle’s

Metaphysics”. However, there is no mere thinking or understanding, for action does not stop

there.154 Understanding is a prerequisite to:155

(a) Organise men justly and accordingly arranging government in the best way possible

which is no small thing because it can mean the difference between violent tyranny,

for example, and enlightened republic, and

(b) Build machines, ships and cities, undertake agriculture, and modify the physical

universe in significant ways and even on a vast scale.

There is a “difference between nature and art, that is to say, between the divine art and ours”.

Machines built by God or nature are machines in their smallest parts ad infinitum. By

contrast, the constituents of, say, a wheel give no indication of the use for which the wheel is

151 “Man is made to be in the visible universe an image and likeness of God himself (Cf. Genesis 1:26.), and he

is placed in it in order to subdue the earth (Cf. Genesis 1:26).” (references in original) Opening statement of

Laborem Exercens Papal Encyclical of Pope John Paul II, 14 Sep 1981 accessed at

http://www.vatican.va/holy_father/john_paul_ii/encyclicals/documents/hf_jp-ii_enc_14091981_laborem-

exercens_en.html 8 May 2011 152 Cassirer, E., Kristeller, P. O., Randall, J. H. Jr (eds and trans.) The Renaissance Philosophy of Man Phoenix

Books, University of Chicago Press 1948; for example, see Mirandola pp.223-5 and Pompanazzi pp. 282-3. 153 Ibid. 154 See also Cusa Idiota de Mente, p.63 on the precise role of understanding in human thought vis-à-vis God’s

thought. Also see the footnote in Merlan, P. From Platonism to Neoplatonism Martinus Nijhoff, The Hague

1968 at p.5, “Understanding (knowledge) is not the only form of significant mental activity of man. We may

enjoy something esthetically [sic]; we may be in empathy with an animal or our fellow-man; any mood is

some kind of mental engagement. But none of these activities is of the order of understanding – they are

attitudes, reactions, modes of being.” 155 “Through work man must earn his daily bread (Cf. Ps 127(128):2; cf. also Gen 3:17-19; Prov. 10:22; Ex 1:8-

14; Jer 22:13) and contribute to the continual advance of science and technology and, above all, to elevating

unceasingly the cultural and moral level of the society within which he lives in community with those who

belong to the same family.” (references in original) Opening statement of Laborem Exercens Papal Encyclical

of Pope John Paul II, 14 Sep 1981 accessed at

http://www.vatican.va/holy_father/john_paul_ii/encyclicals/documents/hf_jp-ii_enc_14091981_laborem-

exercens_en.html 8 May 2011

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intended and indeed are not machines – and certainly are not alive – in any real sense.156

Modernity has seen increasing – and in some cases exponentially increasing – power of

“human art”. Leibniz assisted this process with his concept of vis viva.

Vis viva or effect-producing force

Normally, vis viva belongs in a discussion on the history of physics. It is known in the context

of the debate between Leibniz and the Cartesians on the kinetic energy formula mv2 versus the

Cartesian momentum mv (i.e. mass times speed, or m|v|) which was corrected to mv (mass

times velocity) in 1668 by the non-Cartesians John Wallis, Christopher Wren and Christian

Huygens.157 Vis viva which literally means “living force” is today regarded as kinetic energy

quantified by mv2. It will be seen below that vis viva meant more Leibniz than this formula.

The concept certainly was the subject of debate, and Leibniz fired the opening salvo by

attacking the Cartesian concept of mv in his 1686 essay entitled “Brief Demonstration of a

Notable Error of Descartes”.158 The discussion fits in this chapter, “Ushering in modernity”,

because for Leibniz the effect that a projectile or explosion could produce was what mattered

and that, in turn, was more a result of velocity than of mass though mass plays a role.

Leibniz is not only concerned velocity but also with acceleration and the effect produced by

sudden deceleration. Leibniz writes, “by effect I mean here not any effect whatever but that

for which force is expended or consumed and which may therefore be called violent.”159

(emphasis in original) Leibniz then explains what kind of effect he does not mean and which

machines are, by comparison, “harmless”. Leibniz says, “the ancients had a knowledge of

dead force only, and it is this which is commonly called mechanics, which deals with the

lever, the pulley, the inclined plane (…), the equilibrium of liquids, and similar matters

concerned only with the primary conatus of bodies in itself, before they take on an impetus

through action. Although the laws of dead force can be carried over, in a certain way, to living

force, yet great caution is necessary, for it is at this point that those who confused force in

general with the quantity resulting from the product of mass by velocity were misled because

they saw that dead force is proportional to these factors.”160 According to Meli’s

interpretation, “for Leibniz living force could be represented as the integral of dead force

times an infinitestimal distance”.161

Leibniz agrees that mv is a valid concept with many uses and is only explaining that mv2 is

something qualitatively different. To compare the two, Leibniz writes, “The force which a

heavy body exercises in moving along a perfectly horizontal plane is not of this kind [living

force], because however far such an effect is prolonged, it always retains the same force, and

156 Latta, pp.254-5, §§64-5 157 Iltis, C. “Leibniz and the Vis viva Controversy” Isis Spring 1971, Vol. 62, No.1, pp.21-35 at p.22 158 Hankins, T.L. “Eighteenth-Century Attempts to Resolve the Vis viva Controversy” Isis 1965, Vol. 56, No.185,

pp.281-297 at p.281 159 Leibniz, G.W. Specimen Dynamicum 1695 in Loemker, p.442 160 Ibid., p.439 161 Unfortunately, a translation of De Motu Gravium was not able to be obtained for this thesis, so we are reliant

on Meli’s reading. Meli’s quote is in reference to Leibniz’s essay De Motu Gravium lines 95-101. Meli, D.B.

Equivalence and Priority: Newton versus Leibniz Clarendon Press, Oxford 1993, p.154

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though we use the same principle in calculating this effect also, which we call harmless, we

now exclude it from consideration.”162 (emphasis in original) Leibniz then goes on to discuss

how the “force”, or kinetic energy as we would call it today, of a tiny projectile is absorbed by

and affects even the largest of bodies.

The debate between conservation of momentum or mv and conservation of kinetic energy or

mv2 was an important aspect of the vis viva discussion. However, arguably, to Leibniz’s mind

the more powerful “take away” was the power of explosive force versus the relative

“harmlessness” of “dead force” exemplified by the uniform motion of a heavy body along a

perfectly horizontal plane. The question then becomes – how do we generate and make us of

explosive force? This will lead us into the below discussion of steam power.

First, however, understanding the principles of “effect” is prerequisite to machine-building or

mechanical engineering, since a machine harnesses that effect in a deliberate way. In turn,

modernity embraced the task of consciously harnessing the laws of physics through machines

or otherwise to do useful work in the service of human ends. This is in the same way that the

calculus is the use of symbols as tools of thought in the service of human ends.

Leibniz’s concern with the ability to do useful work is shown where he argues that the

difference between mv and mv2 was:,163

not worthless to consider, nor are they quibblings over words, for they are of the

greatest importance in comparing machines and motions. For example, if power is

obtained from water or animals or from some other cause, by which a weight of 100

pounds is kept in constant motion so that within a fourth of a minute it can be made to

complete a circle of 30 feet diameter, but someone else maintains that a weight of 200

pounds can in the same time complete half the circle with less expenditure of power,

his calculation seems to yield a gain; but you ought to know that you are being

deceived and getting only half the power.

While this argument is straightforward today, it pitched into an ongoing discussion among

leading scientists and engineers of Europe. Experiments by Mariotte, Poleni and ’sGravesende

confirmed that the effect of a moving object varies in proportion to the square of velocity in

the early 18th Century. These experiments were performed with balls accelerated to different

speeds being fired into clay or wax, with the depths of the impressions made being measured.

Of these, ’sGravesende took the most active role in the vis viva debate. In 1720 in his book

Mathematical Elements, ’sGravesende had taken up the question of how to measure the ability

of an “action of power” to overcome obstacles.164 This is the Leibnizian concern with the

effect of a force or “power”. In 1722, ’sGravesende proceeded to defend Leibniz’s idea of vis

viva.165 In 1733, Poleni had published an article reporting the results of an experiment in

which balls were dropped onto tallow to compare the depths of the impressions made. His

analysis showed that the “force in motion” was proportional to the square of the velocity. A 162 Ibid., p.442 163 From Part I of Specimen Dynamicum 1695 in Wiener, p.137 164 Hankins, T.L. “Eighteenth-Century Attempts to Resolve the Vis viva Controversy” Isis 1965, Vol. 56, No.185,

pp.281-297 at p.287 165 Ibid.

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Swiss mathematician Calandrin published an anonymous article in the same issue of the same

journal saying that since the resistance of the tallow was constant, equal force should be

consumed in equal times. Feeling compelled to respond to the Calandrin article, ’sGravesende

replied disagreeing that equal amounts of “force” are consumed in equal times. The question

of why the impressions left in clay by a cylinder in motion were not proportional to vis viva

was taken up, as this seemed to contradict the theory. ’sGravesende argued that the early

deceleration split seconds after striking the clay and making the initial impression reduced the

ability of the cylinder to drive deeper into the clay. This was confirmed by experiments with a

series of parallel adjacent taut strings that are struck by a projectile. More strings are broken

per unit time while the object is moving rapidly than when it has slowed down.166

’sGravesende noted that collisions are not instantaneous but proceed in a continuous fashion

causing the gradual deformation and deceleration of the bodies upon and after collision or,

during collision. ’sGravesende explained that, likewise, in a simple machine a small mass

may counterbalance a larger provided it is moving proportionately faster at the instant the

machine starts. According to Hankins, the most aggressive detractors of Leibniz’s concept of

vis viva d’Alembert and Boscovich missed key points and, in retrospect, made little

progress.167

The purpose here is to introduce the vis viva concept and suggest how it fit in Leibniz’s

overall interests and unfolding agenda.

Machines are indispensable to the concept of modernity

Machines increasingly were being invented and used during Leibniz’s lifetime. Essentially,

control of man over nature was on the rise. A machine systematises a physical process like a

Universal Characteristic would systematise a mental or intellectual process, and Leibniz was

interested in both. The two intersected in the calculating machine that Leibniz designed. In a

sense, the calculus is an example of a specific kind of Universal Characteristic because a

mechanical algorithm is availed to answer questions about a huge class of (non-linear)

functions.

Leibniz collaborated with Denis Papin on his invention of the steam engine, providing input

including relating Papin’s work back to Leibniz’s concept of vis viva and also providing

pragmatic mechanical suggestions.

Christian Huygens had mentored Papin168 and Leibniz.169 Papin had worked as Huygens’

ammenuensis (“scribe”) and had built machines under his direction.170 Huygens had invented

166 Ibid. 167 Ibid., pp.283-6, 291ff 168 Klemm writes, “Near the end of the century Huygens’s assistant Denis Papin who, through working on

problems with gunpowder, hit on the steam engine in 1690.” Klemm, F. A History of Western Technology.

History of Science and Technology reprint series Iowa State University Press, Ames (1954), 1991 accessed at

http://www.cmpense.org/worksinprogress/summary/Klemm.html 17 May 2012 169 For example in 1672 it was Huygens who suggested Leibniz summing the series 1/1 + 1/3 + 1/6 + … in

which the denominators are the triangular numbers. Bos, H. J. M. “Newton, Leibniz and the Leibnizian

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a steam pressure cooker powered by gunpowder. Leibniz then worked with Denis Papin to

invent the steam engine. This may have helped Leibniz formulate and crystallise his idea of

vis viva. Though there seemed later to have been a falling out between Papin and Leibniz,

apparently due to resentment on Papin’s side for unknown reasons.171 Leibniz’s participation

represents his involvement in systematising methods for modifying or improving the human

condition by effecting change in the physical world, whether by hauling earth or ore from a

mine shaft, pumping water from a mine shaft, or accelerating a transportation vessel rapidly

over the sea.

The dawn of modernity was characterised by the rise of human commandeering of machine

power, which was a result of contemplation and experiment to uncover physical principles on

the one hand, and deliberate design as well as trial-and-error with machines on the other. The

power of machines would hardly exceed what Archimedes’ machines were able to do without

the vis viva or concentrated, violent or explosive force which Leibniz’s advocacy forces us to

consider as distinct from passive force.172

The association between modernity and the rise of machines is also represented in Leibniz.

Leibniz’s role in designing machines receives little mention in the Leibniz literature, in favour

of his mathematical work, especially the calculus, and his metaphysical thought, especially

monads. Yet, Leibniz himself wrote that if he could spend time on whatever he wished, then

he would design machines full-time.

Papin’s steam engine design was published in the Leipzig Acta Eruditorum, a journal edited

by Leibniz, of August 1690 with the diagram in Figure 1.

Papin was using the idea of explosive force as a continuation of Huygens’ experiments with

gunpowder. Leibniz concept of vis viva was developed after Leibniz was aware of Huygens’

work, and was an effort to give the different kinds of force a theoretical basis. There are

letters from Leibniz to Papin on the vis viva idea.173 The question of priority is not of interest,

only the fact that Leibniz was involved in the earliest experiments with steam power.

tradition” in Grattan-Guinness, I. (ed.) From the Calculus to Set Theory, 1630-1920: An Introductory History

Duckworth: London 1980, p.61 from Leibniz, G. W. Writings (Mathematische Schriften) Gerhardt, C. I. (ed.)

1849-1864 Berlin and Halle, vol. 5, p.405 170 Freudenthal, G. “Perpetuum mobile: the Leibniz-Papin controversy” Studies in the History and Philosophy of

Science Vol. 33 (2002) 573-637, p.599 171 Ibid. 172 According to Klemm, Papin’s contribution to the steam engine which further developed Huygens’ design –

and Leibniz’s collaboration with Papin – was an important marker of the end of the Baroque Period and the

beginning of the Age of Rationalism early in the 18th Century. Klemm, Chapter 3 “The struggle for a new

prime mover” pp.208ff. C.f. Giedion, S. Mechanization takes command: a conttribution to anonymous

history Norton & Co. New York 1969 first published by Oxford University Press 1948. The book covers the

mid-15th Century to the early 20th Century. 173 Referring to August 1690 issue of the Acta Eruditorum which explained his steam machine, Papin wrote to

Count Philipp Ludwig von Sinzendorff in the early 1690s, “As water has the property that it is converted by

fire to steam … and can then be easily condensed again by cold, I thought that it should not be too difficult to

build engines in which, by means of moderate heat and the use of only a little water, that complete vacuum

could be produced which had been sought in vain by the use of gunpowder. … I have ascertained by

experiment that the piston, raised by the heat to the upper part of the cylinder, will immediately return again

to the bottom, and this happens several times in succession so that one might suppose that there was no air at

all exerting pressure from below or offering any obstacle to the descent of the piston. Now my tube, whose

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Figure 1: Denis Papin’s Atmospheric Steam Engine from Acta Eruditorum August 1690

with caption from Klemm, p.221

Leibniz’s mathematical work is usually if not always considered separately from his interest

in mechanics. Leibniz was interested in the problems of mechanics (time, distance and

motion) precisely due to his interest in machines. He had pragmatic ends in mind. In fact, the

demarcation between mathematics and mechanics is artificial and probably was not known to

Leibniz in the way that it is presumed by modern readers.

The idea that Leibniz started with abstract curves and then found these to be helpful in

problems in the domain of mechanics has some truth, 174 but for the most part Leibniz was

thinking about mechanics all the time and from the start. Leibniz from the outset regarded

geometry and his calculus as worthwhile pursuits because of what they add to human

capability in society and in the physical world. Grosholz refers to Leibniz’s synthesis of

different domains, “Because his [Leibniz’s] analysis deals with magnitude in general, it can

also apply to mechanics – to distance, time velocity, and force; because it does not eschew the

infinitary, it can apply to continuous motion.”175 Later on the same page, Grosholz says, “A

fuller integration of mechanics and mathematics depends on precisely the reorganization of

mathematical domains”. Further, “Leibniz’s synthesis does not take place merely because he

diameter is only 2 ½ inches is nevertheless able to to raise 60 lb. the whole distance through which the piston

falls. And the tube does not even weigh 5 oz. … I have also proved that one minute is sufficient time for a

moderate fire to force the piston to the top of the tube. … If consideration is given to the magnitude of the

force that can be generated by this means, and the small cost of the wood that has to be used, it must certainly

be admitted that this method is far preferable to the use of gunpowder. … It would lead us too far afield to

discuss how this discovery could be applied to extract water from the mines, to throw bombs, to sail against

the wind or other similar applications which might arise.” (Klemm, p.221-222) 174 Grosholz, E. “Was Leibniz a mathematical revolutionary?” in Gillies, D. Revolutions in Mathematics Oxford

University Press, New York, 1992, pp.117-133 175 Ibid., p.126

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employs abstract algorithms that can be instantiated in different domains, but also because the

synthesis engenders hybrids that exist simultaneously at the overlap of different domains.”176

In fact, Leibniz is always working in both domains, and does not really see the difference

between them. Grosholz says, “Transcendental curves like the tractrix and the catenary, and

the ellipse re-imagined as a trajectory, will illustrate my point.”177 However, these curves also

illustrate the opposite point – that Leibniz’s work in mathematics was work in mechanics,

which was ultimately motivated by his interest in machines, at the same time.

What are regarded as different domains in the late 20th and early 21st Centuries may not have

been in Leibniz’s time, when it was natural for thinkers to be across multiple “domains” most

of the time, as indeed most were.178

In describing the constellation of scientists influenced by Mersenne, which included Rene

Descartes, Pierre Gassendi, Gerard Desargues, Pierre de Fermat, Gilles Personne de Roberval

and Galileo Galilei, Cohen wrote that they were trained in a “liberal approach to study that

embraced many fields” and “were, in fact, philosopher-scientists whose attitudes pervaded the

times and helped provide a very special basis for the establishment of the Paris Academy”.179

In a similar vein, Bell describes the intellectual environment of Christian Huygens,180 the first

president of the (French) Royal Academy.

Political influences on and of Leibniz

The breadth of scientists in Leibniz’s time went even further than Cohen and Bell have said.

Scientific and philosophical thought was connected with the necessities and potentialities of

social and political life. Indeed, Mercer constructed the theory of “conciliatory eclecticism” to

explain the philosophy of both Leibniz and his teacher Jakob Thomasius as emanating from

the religious conflict that gave rise to the Thirty Years War (1618-1648) which Thomasius

lived through. Leibniz was born towards the end of that war, in 1646.181 In a sense, the Thirty

Years War was a continuation of European religious strife in the vein of the foregoing century.

That religious conflict affected intellectuals throughout Europe and gave a greater sense of

mission and urgency to their deliberations and activism. It certainly was a motivation for

Bruno in the 16th Century, many decades even before the Thirty Years War. “Wherever Bruno

travelled within Europe, doctrinal intolerance and endemic slaughter in the name of God

reassured him that only a spiritual and intellectual revolution could ever disassociate religion

176 Ibid., pp.126-127 177 Ibid., p.127 178 In the same vein, an information-theoretic approach might not be helpful when studying 17th century thinkers

as Grosholz attempted to do. See Grosholz, E. “Partial Unification of Domains, Hybrids and the Growth of

Mathematical Knowledge” in Grosholz, E. and Breger, H. (eds.) The Growth of Mathematical Knowledge

Kluwer, Dordrecht 2000 179 Cohen, A. Music in the French Royal Academy of Sciences: A study in the evolution musical thought,

University Press, Princeton NJ 1981, pp.3-6 180 Bell, A. E. Christian Huygens and the Development of Science in the Seventeenth Century E. Arnold, London

1947, p.47 181 Mercer, C. Leibniz’s Metaphysics: Its Origins and Development Cambridge University Press, Cambridge

2001, pp. 80-110

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from murder, horror, and endless pain.”182 Yates has written extensively on Catherine de

Medici’s use of talismans and astrological rituals for the “pacification of the wars of

religion”.183 In any case, as far as Leibniz’s contemporaries were concerned, the Thirty Years

War had a major influence on the political and theological thinking of the time, much as WW

II influenced political and economic thought for the early post-WW II decades.

In fact, Leibniz in Theodicy did not refrain from addressing the protestant side of the Thirty

Years conflict:184

Luther’s book against Erasmus is full of vigorous comments hostile to those who

desire to submit revealed truths to the tribunal of our reason. Calvin often speaks in the

same tone, against the inquisitive daring of those who seek to penetrate into the

counsels of God. He declares in his treatise on predestination that God had just causes

for damning some men, but causes unknown to us. Finally M. Bayle [Pierre Bayle,

1647-1706] quotes sundry modern writers who have spoken to the same effect (Reply

to the Questions of a Provincial, ch. 161 et seq.).

Leibniz refers to Pierre Bayle (1647-1706). Bayle typified some aspects of the time and is

regarded as one of the most prominent men of letters of the 17th Century.185 As a Protestant in

France, Bayle suffered and fled religious persecution living much of his life as a refugee in

Holland.186 Bayle’s best-known work, the Dictionnarie historique et critique (“Historical and

Critical Dictionary”), published in 1696, comprises over 2500 articles on people from before

Christ to Zeno to Hobbes. The Dictionnarie is sometimes called the “arsenal of the

Enlightenment” because it was used by activists and writers for material for their respective

arguments. It is estimated to be the “single most popular work of the eighteenth century”. The

issues of religious tolerance, respect for the conclusions of the consciences of others, and the

problem of evil were central concerns in Bayle’s writings.187 Unfortunately, we do not have

the space or time to examine Bayle’s ideas further here.

Johnson had this same thought:188

Leibniz lived during a period of intense crisis. Dynamic individualism, in Church and

State, threatened to reduce the life of Europe to chaos. There was a desperate need to

achieve a harmony which would not destroy the fruitful forces of individualism.

Leibniz set himself to formulate a comprehensive philosophy which would serve as

182 White, M. The Pope and the Heretic: The true story of Giordano Bruno, the Man Who Dared to Defy the

Roman Inquisition Harper Collins 2001, p.29 183 Yates 1964, p.176; Yates, F. The French Academies of the Sixteenth Century Warburg Institute, University of

London 1947, pp. 236 ff.; and Yates, F. The Valois Tapestries Warburg Institute, University of London 1959,

pp. 82 ff. 184 Leibniz, G.W., Huggard, E.M. (trans.) Theodicy §49 Project Gutenberg edition 2005 accessed at

www.gutenberg.com, p.101 185 ARTFL Project, Project for American and French Research on the Treasury of the French Language, of the

Department of Romance Languages and Literatures, University of Chicago. Accessed at http://artfl-

project.uchicago.edu/node/60 on 22 May 2012 186 Lennon, T. M. and Hickson, M. “Pierre Bayle” Stanford Encyclopedia of Philosophy article first published

2003 revised 2008. Accessed at http://plato.stanford.edu/entries/bayle/ on 22 May 2012 187 Ibid. 188 Johnson, A.H. “Leibniz’s method and the basis of his metaphysics” Philosophy 1960 vol. 35, p.60

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the intellectual foundation for a new age which would facilitate fulfilment of the best

dreams of scientists and practical men, saints and sages. Leibniz did not philosophize

in a logical vacuum.

Loemker says that Leibniz had hoped that his metaphysics “would be adopted and made a

blueprint, so to speak, by men of good will (honestas) for the restoration of European order”

and it may “be regarded as the intellectual high point of the century’s efforts toward a

renovation of Europe through the ideal of loyalty and obedience to a universal nature and

moral order.”189 Loemker points out that Descartes and Spinoza, like Locke, saw no

imperative to particular social rules. Descartes separated the objective from the subjective in

his two-level order of, on the one hand, creator and, on the other hand, created “which must

interact, yet cannot interact since they have no common nature which could make this

possible”. Spinoza separated God from “the everyday evaluations of man” and is “accessible

only to the mind which is completely disciplined”. However, life in society “is recommended

on the commonsense ground of utility and conservation [preservation?], and such active

affections which contribute to them. There is no great overarching order of commands

whereby the social order is to be regulated”.190 We will see below that Leibniz distinguished

salutary social influences from detrimental ones not purely on the grounds of utility and

preservation. This was bound up with Leibniz’s conception of the nature of Man and the

unique role and position in the universe allocated to humanity by God.

Seeking to understand Creation as a whole

In discussing the analysis of Grosholz, we review the thread from the pre-moderns to

modernity.

Grosholz finds it impressive that Leibniz’s calculus could be applied to enrich Kepler’s work

on the solar system. Yet, it would make sense for Leibniz to have considered the problems

involved in Kepler’s grappling with the structure and harmony of the solar system as a proxy

for other problems in science and machine design. Planetary motion was one of the active

“research areas” of the period, a bit like “climate change” was in the early 21st Century. Thus,

it is unlikely that Leibniz simply stumbled on the fact that his calculus was useful for

questions relating to planetary motion; Leibniz would have been aware of Kepler’s

contribution and of open problems left by Kepler. Huygens would surely have mentioned the

problem of planetary motion and Kepler’s work to Leibniz. Further, the fact that Leibniz read

so many of the Greek classics in his teens makes it almost certain that he’d have been aware

of the problems in understanding the solar system which could have drawn him to Kepler who

represented the state of the art on the question of planetary motion in Leibniz’s time.

189 Loemker, L. E. Struggle for Synthesis: The Seventeenth Century Background of Leibniz’s Synthesis of Order

and Freedom Harvard University Press: Cambridge USA 1972, p.127 190 Ibid., p.130

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Grosholz raises a supposed contradiction at the end of a paper on Leibniz191 as a conundrum.

Grosholz says that modern problems in physics such as relativity theory and quantum theory,

pose grave philosophical problems because if we call them part of mathematics, and so mere

patterns and relational structures, we cannot explain how they can play the role of the

furniture of the universe, as in contemporary physical theory they surely do. If we call them

part of the description of nature, we must wonder how nature has come to look so exact and

immaterial. If we call them hybrids, they seem to contain an internal contradiction.192

Grosholz has raised nothing less than the ancient problem of duality. That is, what is the

relationship between abstract mathematical structure which is outside and separate from the

physical universe, and the physical universe which seems to realise or embody abstract

mathematical structures. This problem was first dealt with no later than Plato (c.427-c.347

BCE). According to Plato, arithmetic comes first whence plane geometry is derived, whence

solid geometry. On these foundations sit astronomy and harmonics.193 The fourfold structure

of arithmetic, geometry, astronomy and music is known as the quadrivium.

The primacy of the quadrivium was maintained by Neoplatonists Iamblichus (c.242-327 CE)

and Proclus of Athens (412–485 CE). While the quadrivium was part of the curriculum of

medieval universities, it should not be regarded as naïve, arcane or quaint for that reason.

Given the sequence set forth by the quadrivium, Kepler’s hypotheses regarding the

relationship between the Platonic solids and the structure of the solar system, and between

musical harmony and the design of the solar system, are natural and even canonical.

The quadrivium resolves the problem of duality within itself. In the transition from geometry

to astronomy, we cross from the abstract to the physical, but all within the framework of the

quadrivium. In short, it need only be said that the quadrivium defines structure and structure

comes first. Thus, the quadrivium precedes anything perceived, including by measurement, to

be in the physical universe. It forms part of the (imperceptible) rules governing the universe.

It is connected with the best of all possible worlds doctrine, because to adhere to the structure

of the quadrivium provides the best design for, at least, the non-living part of the universe. We

can see the effects of the quadrivium not the quadrivium itself. Is it “part of” the universe? In

the same way, the rules of cricket are part of a cricket game, though those abstract rules are

not perceptible in the very physical acts of catching, throwing and hitting a cricket ball.

Unlike cricket, the universe has no definite rule book we can open as the final word or arbiter;

we have to work it out for ourselves. Within the confines of the quadrivium, “Geometry is

prior to astronomy,” as Proclus said. Failure to note Kepler’s Neoplatonic mindset results in a

191 Grosholz, E. “Was Leibniz a mathematical revolutionary?” in Gillies, D. Revolutions in mathematics Oxford

University Press: New York, 1992, p.117-133 192 Ibid., p.133 193 The literature on the quadrivium is vast. See http://scienceworld.wolfram.com/biography/Plato.html accessed

26 Feb 2012 for a summary. For Plato’s advocacy, see The Republic Book VII in Rouse, W.H.D. (trans.)

Great Dialogues of Plato Signet Classic, New American Library a division of Penguin, New York 1999,

pp.324-331 culminating at p.332 with the name “dialectic” being given to the progress of thought through the

quadrivium, likening it to a turning away from the shadows and progression through a tunnel upward to the

sun in the context of the allegory of The Cave. Plato says much more about music in Book III of The

Republic.

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misunderstanding of his method.194 After the quadrivium comes the hybrid between

mathematical reasoning and observation. Last and least is pure observation.

The quadrivium was core to learning at least as late as the 17th Century. 195 Leibniz, at least

earlier in his career, said that most problems in physics can be resolved into problems of pure

geometry.196,197 However, Johnson interprets Leibniz as having gone farther than he did, in

regarding Leibniz’s ten maxims on the Art of Discovery as being tantamount to rules of

geometrical reasoning.198

Much of 20th Century, and 21

st Century, science has a tendency to start with the observations.

Further, there is a pre-occupation with things that we can physically observe and visualise in

the mind. There are exceptions, such as string theory. As a civilisation, we have forgotten how

we reached the starting line of 20th Century science. Franklin and Newstead’s defence of the

reality of indefinable real numbers is a sally against “empiricist idealism”.199 Of course,

empiricist idealism did not begin in the Twentieth Century and perhaps existed in more

strident form in certain circles in earlier centuries.

Geometry as a tool to understand Creation as a whole

To Kepler, the beauty and perfection of mathematics – especially geometry – reflected the

perfection of God’s methods. Astronomy, being representative of Creation on the larger scale,

had to reflect this beauty and perfection.200 Such a contention tends to be associated with

Renaissance Platonism and its supposed commitment to vitalism and natural magic. While

Stuart Brown has done much to dispel this misconception,201 it persists in abundance. For

194 For example, Lawrenz refers to Kepler’s Mysterium Cosmographicum and Harmonice Mundi as “luxuriant

cosmological fantasias” Lawrenz, J. Leibniz: Double-aspect ontology and the labyrinth of the continuum

2007 PhD thesis, University of Sydney, p.23, note 5 195 Cohen, A. Music in the French Royal Academy of Sciences: A study in the evolution musical thought,

University Press: Princeton NJ 1981, pp.3-5. Cohen writes of Mersenne who was influential in the

intellectual life of Paris in the early 17th Century, and the parenthetical comments are in the original:

“Having derived his thinking from the platonic traditions of the Renaissance (in which music was considered

‘the image of the whole encyclopedia’), Mersenne assigned a special role to music in his own system, where

it formed an essential part of mathematics, ‘utile à toutes le sciences.’ Certainly, this view of music reflects

its place in the quadrivium of the medieval artes liberales (the four mathematical disciplines that had their

common basis in numerical ratio and proportion: “arithmetic - pure number, music - applied number,

geometry - stationary number, astronomy - number in motion”), which continued to form the foundation for

university studies through the Renaissance and into early modern times.” 196 Johnson, A. H. “Leibniz’s method and the basis of his metaphysics” Philosophy 1960 vol. 35, 51-61, pp.52-

53 197 Letter to Ferrault, 1676 “All problems in gravitation, magnetism, electricity and light are explicable by the

resolution of a few problems of pure geometry” in Wiener, pp.xxi-xxii 198 Johnson, A. H. “Leibniz’s method and the basis of his metaphysics” Philosophy 1960 vol. 35, 51-61, p.53 199 Franklin, J. and Newstead, A. “On the Reality of the Continuum; Discussion Note: A reply to Ormell,

‘Russell’s Moment of Candour’, Philosophy” Philosophy (published by the Royal Institute of Philosophy) 83

2008, p.121 200 Duncan, A.M. trans. Kepler, J. Mysterium Cosmographicum Abaris Books, Janus Series Norwalk USA 1981,

p.57 201 Brown, S. “Leibniz and Berkeley: Platonic Metaphysics and ‘The Mechanical Philosophy’” Chapter 16,

pp.239-253 in Hedley, D. and Hutton, S. (eds) Platonism at the Origins of Modernity: Studies on Platonism

and Early Modern Philosophy Springer 2008

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example, Lawrenz wrote that the Mysterium Cosmographicum and Harmonice Mundi were

“luxuriant cosmological fantasias integrating mysticism, music, mathematics, Pythagorean

number lore, the doctrines of the Timaeus”.202 Lawrenz then says that Leibniz distanced

himself from Kepler’s work, “having recognised during his Paris sojourn that its mathematics

was woefully inadequate to the task”. On the contrary, we can see Kepler in many places in

Leibniz’s metaphysics including in the “best of all possible worlds” doctrine. Also, the

inadequacy of Kepler’s mathematics had nothing to do with his selection of the Platonic

solids hypothesis. Rather, that hypothesis was a natural result of a priorist thinking. It would

not have been possible to be an a priorist without a familiarity with standard Pythagorean and

Platonic ideas such as the quadrivium and platonic solids.

Let us try to draw an analogy close to the heart of 21st Century readers. The art of ordering

human affairs is increasingly being addressed through the formal sciences, “‘the sciences of

complexity’ or ‘sciences of the artificial’” – typified by optimisation – amongst which

Franklin has attempted to find a unifying thread.203 Belief in a Creator of the universe who

has certain qualities of beneficence leads one to conclude that there must be structure

underlying the physical universe whose creation was itself an “artificial” act. If well-

organised humans structure their activities using formal sciences, what science of the artificial

did the Creator use? The first principles of structure, the quadrivium, must be at or near the

foundation, or so it would have been reasonable for the Renaissance and early post-

Renaissance scientist to believe.

Understanding Creation as a whole, and improving upon it

The burgeoning of modernity, as we argue here that modernity should be defined, is seen in

the correspondence between Leibniz and Papin. Their collaboration did not arise in a vacuum

but in the drive towards national development for the benefit of the General Welfare of the

nation of France. As minister of the young French King Louis XIV, Jean Baptiste Colbert

initiated a project to discover and make effective a source of power capable of enabling a

dramatic human advance. The project was put into motion as a national effort.

The project was conceived when the drive for development had outstripped the power sources

available. For example, Klemm explains that the:204

...vast and costly establishment at Marly [14 water wheels in the river Seine, each 40

feet in diameter driving 442 pumps], and its relatively small output [80 horsepower]-

shows us clearly the limits of the old power-machine technology. To seek a more

efficient and reliable prime mover than the traditional wind and water wheels was in

fact to become the urgent task of the technology of that period.

202 Lawrenz, J. Leibniz: Double-Aspect Ontology and the Labyrinth of the Continuum of Sydney PhD thesis

2007, p.23, footnote 5 203 Franklin, J. “The Formal Sciences discover the Philosopher’s Stone” Studies in History and Philosophy of

Science Vol. 25 No. 4 1994 pp.513-533, p.18 204 Klemm, p.208

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Philosopher scientists and French nation-building

In 1666, Colbert established the Academy of Sciences in Paris to further this purpose, and

Christian Huygens was recruited as the first president of the new Academy. Thus, Colbert was

following the prompting of the ‘useful science’ idea. We do not know whether Colbert

acquired this idea from Francis Bacon.205 Huygens proposed a program including research

into the power of gunpowder of which a small portion is enclosed in a very thick iron or

copper case, research into the power of water converted by fire into steam, and experiments

with vacuum pumps, wind-powered engines, and the communication of force by the collision

of bodies.206

The experiments carried out on the basis of these suggestions were the prelude to the

development of a new power-engine. Huygens’ suggestions followed the work of Guericke

who had shown in 1661 that a piston, forced by air pressure into an evacuated cylinder, can be

utilized to perform work. Guericke’s cylindrical vessel was 15 inches in diameter and just

over 21 inches long; it was evacuated by an air-pump invented by Guericke. In 1664 Caspar

Schott announced Guericke’s experiments on obtaining power by pistons forced through a

metal cylinder by air pressure.

In 1672, Huygens acquired two students: Leibniz the 26-year old diplomat, and Denis Papin a

25-year old French medical doctor who was introduced by Madame Colbert. Within 12

months, Huygens, Leibniz and Papin had modified the Guericke air pump into an engine that

could transform the force of exploding gunpowder into useful work.207 Huygens demonstrated

a model “gunpowder engine” to Colbert. In 1673 Huygens wrote this about the model:208

The violent action of the powder is by this discovery restricted to a movement which

limits itself as does that of a great weight. And not only can it serve all purposes to

which weight is applied but also in most cases where man or animal power is needed,

such as that it could be applied to raise great stones for building, to erect obelisks, to

raise water for fountains or to work mills to grind grain …

It can also be used as a very powerful projector of such a nature that it would be

possible by this means to construct weapons which would discharge cannon balls,

great arrows, and bomb shells … And, unlike the artillery of today these engines

would be easy to transport, because in this discovery lightness is combined with

power. This last characteristic is very important and by this means permits the

discovery of new kinds of vehicles on land and water.

And although it may sound contradictory it seems not impossible to devise some

vehicle to move through the air …

205 C.f. Franklin, J. “‘Useful science’, as an idea, is Baconian, but science as an accepted route to profit, military

superiority is an eighteenth-century development.” in “Artifice and the Natural World” in Cambridge History

of Eighteenth Century Philosophy CUP p.842 206 Klemm, p.212 207 Ibid., p.212 208 Ibid., p.213

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Leibniz had invented a mechanical computer in 1671, a year before Leibniz was introduced to

Huygens. The computer was built in 1673.209 Working alongside Huygens and Papin, Leibniz

was active as an inventor of machines that could perform physical work. Brown and Calvör

describe Leibniz’s work between 1678 and 1679 on his own design for a wind-powered pump

to keep the mines in the Harz mountains dry.210,211 Leibniz personally supervised construction

of his mine pump and personally paid for part of it.212 Klemm speculates that the failure of the

pump was possibly due to Leibniz’s frequent absence from the site and the poor skills of the

workers. Despite the difficulties, Leibniz then designed a machine which sought to overcome

the limitations that had plagued earlier attempts. Leibniz’s hand drawn diagram is included

here as Figure 2. In the end, the Harz mine pump project was unsuccessful and very expensive

to his employer in lost potential income.213

209 Calvör, H. Historisch-Chronologische Nachricht … des Maschinenwesens … auf dem OberharzeBrunswick,

1763 translated by Dorothea Waley Singer in Klemm, pp.208-9 210 Ibid. 211 Brown, R. C. Leibniz unpublished, Chapter 11 “Epilogue”, pp.163-4 212 Klemm writes that Leibniz personally paid for the pump. Richard Brown qualifies this, writing that it was

originally agreed with the Leibniz’s employer the Duke Johann Friedrich that Leibniz would personally paid

for the prototype mine pump for test purposes, in September 1679. However, in October 1680 Leibniz’s share

was reduced to one third with the balance to be provided by the Duke and the Mining Office. Brown, R. C.

Leibniz unpublished, Chapter 11 “Epilogue”, p.163 213 Brown, R. C. Leibniz unpublished, Chapter 11 “Epilogue”, pp.163-4

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Figure 2: Leibniz’s design for a wind-driven water pump (Klemm, p.211)

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An era of pro-nuclear advocacy

An anonymous article from the late 17th Century entitled “To the greater glory of God” refers

to a letter by Huygens on the potential of gunpowder. The promise and danger in the use of

gunpowder in that period mirrors today’s debate about nuclear energy. The writer is on the

“pro” side, and he cites Renaissance-like arguments similar to those used by today’s

proponents of nuclear energy. The letter defends Huygens’ experiments with gunpowder.214

The letter illustrates the optimistic spirit of technological progress for the benefit of

humankind which defines Leibniz’s outlook. This optimism, in spite of the Thirty Years War,

characterized the period of Leibniz’s career. The letter makes the transition from the

philosophical regard for the primacy of Man to its practical implications and realization in

machines. The letter also relies most heavily on the concept of vis viva without using the term.

The letter is anonymous, and given Leibniz’s diplomatic employment, young age (late 20s) at

the time the letter was published and association with Huygens, one wonders whether it was

written by Leibniz himself or one of his friends perhaps at Leibniz’s instigation.215

Leibniz’s optimism about human nature and rejection of the contention that humans cannot be

trusted is more explicit when he explains why the health of the mind and body are too often

neglected. He says, “those who reflect find more reason to admire the excellence of human

nature than to despise it.”216 Leibniz writes that “empirical physics is useful for human life

and should be cultivated in the state” and that “new experiments are to be undertaken at

public expense, and only men outstanding not merely in science but in virtue are to be placed

in charge.”217

Despite the failure of Leibniz’s water pump initiatives, his collaboration with Huygens and

Papin continued. Leibniz supplied a number of practical suggestions, right up to Papin’s

invention of steam locomotion and Papin’s proposal to use it to power a steamboat.

Klemm indicates that Thomas Newcomen, often credited with the invention of steam-

powered locomotion,218 was really riding on the back of Papin and Leibniz’s work.219

Arguably, Newcomen’s engine was a scaled-up version of Papin’s atmospheric steam pump

based on a combination of two of Papin’s earlier ideas: to use a lever to transmit power from

one pump to another (from 1687) and to use steam to create a vacuum and drive a piston

(from 1690).

214 Klemm, pp. 218-220 from Ad majorem Dei gloriam published in Nouvelles de la Republique des Lettres

Amsterdam 1695. The article is extracted in Appendix 1. 215 Brown, R. C. Leibniz unpublished, Chapter 11 “Epilogue”, pp.175, 179 216 “Essay on a new plan of a certain science” in Wiener, p.583 217 “On the elements of natural sciences” ca. 1682-4, Loemker, pp.281, 282 218 E.g. see Franklin, J. “Artifice and the Natural World” in Cambridge History of Eighteenth Century

Philosophy Cambridge University Press, p.843 219 Klemm, pp.226-227

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Participating with God in Creation

Leibniz ties physical action to the mind of God, analogously to how he participates in the

design of machines to the mind of humans. “For we have now seen, from the pre-established

harmony, that God has ordered all things so wonderfully that corporeal machines serve minds

and that what is providence in a mind is fate in a body.”220 That is, minds are in the driver’s

seat. This has the end-implication that laziness of mind in an individual, a nation or a

civilisation is self-correcting for it leads, inevitably, to conditions which will force that mind

of the individual or the collective, perhaps in a future generation, to reconsider.221

Arguably, the power of Man over nature defines modernity. Man could not have this power

were the design of the universe not rational for otherwise there would not be sufficient order

and predictability in the universe for Man to effect change in it. A rational universe, in turn,

requires a rational conception of the Creator of the universe. The power of Man to effect

change in the universe is summed up at a higher order of magnitude in Leibniz’s conception

of dynamics. The concept is addressed in the correspondence between Leibniz and Papin on

the power of steam to lift a column of air and more. It is indirectly brought out by Leibniz in

his Specimen Dynamicum (1695). However, the argument in Specimen Dynamicum mainly

goes to why the ancients only had half the story with dead force, versus vis viva, and why

Leibniz believed Cartesian doctrines on matter, force and velocity to be wrong.

220 Loemker, p.593 (Letter to Hansch, July 25, 1707) 221 Thus, Leibniz would agree that the divine mind does “design through us” albeit that we have free will. We

disagree with Austin Farrer in his commentary on Theodicy (November 24, 2005 [EBook #17147], pp.32-

33):

And perhaps some such element enters into all our choices, since our life is to some extent freely

designed by ourselves. If so, our minds are even more akin to the divine mind than Leibniz realized. For

the sort of choice we are now referring to seems to be an intuitive turning away from an infinite, or at

least indefinite, range of less attractive possibility. And such is the nature of the divine creative choice.

The consequence of such a line of speculation would be, that the divine mind designs more through us,

and less simply for us, than Leibniz allowed: the ‘harmony’ into which we enter would be no longer

simply ‘pre-established’. Leibniz, in fact, could have nothing to do with such a suggestion, and he

would have found it easy to be ironical about it if his contemporaries had proposed it.

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Chapter 4: Idea of truth

Introduction

We begin with the nature of the pursuit of truth, which touches on mathematics, the

limitations that Leibniz found in mathematics, and the relationship of mathematics to

metaphysics. This will take us into the domain of Neoplatonic exactitude which anticipates

the next chapter. We will be required to introduce Paolo Sarpi and the limitation on deductive

reasoning when it is constrained by the empiricist ideology. This will take us into a bridge

from Paolo Sarpi to the English Royal Society. Both Galileo and Newton had a doctrine of

how discovery takes place, and we see the continuum on increasing empiricist constraint

stepping upwards from Galileo to Sarpi to Newton. Relevant to this is a correspondence

between Sanderson’s 17th Century textbook on logic and Newton’s doctrine of the discovery

process, and especially Newton’s bias against hypothesis, both explored in the next chapter.

Contrary to a desire to make science appear to be “objective”, we argue that pure positivism is

not possible in either science or mathematics, nor can metaphysics be removed from science.

While having a Neoplatonist orientation in many matters of science and philosophy, Leibniz

saw the necessity for formal reasoning in science. Rather than being an innovation that

Leibniz added to Neoplatonism, rigor is found in Platonism itself.

Minds can successfully search for truth

In the previous chapter, we explained that modernity was about the accessibility of scientific

principles crystallising in pragmatic tools or machinery for physical influence by humans in

the universe. In this chapter, we attempt to lift these considerations to the concept of truth

itself.

That truth is discoverable via the exercise of reason was a presumption maintained by

Leibniz. This includes physical and metaphysical principles, and principles of human purpose

and conduct. At least, if truth does not exist or is not discoverable then Leibniz makes no

sense. More importantly, since we never fully know truth, it is the process to reach towards

truth that is of greatest concern and, when it comes to science, the only concern.

The ability of the human mind to access truth or parts of truth gives the mind special place in

the universe. Leibniz saw a relationship between the human mind and the divine, which

appears to be akin to how Nicolaus of Cusa understood the relation between the mind and the

divine. Leibniz begins this passage in a letter with reference to the Neoplatonist Plotinus:222

as Plotinus rightly said, every mind contains a kind of intelligible world within itself;

indeed, in my opinion it also represents this sensible world to itself. But there is an

infinite difference between our intellect and the divine, for God sees all things

adequately and at once, while very few things are known distinctly by us; the rest lie

222 Letter to Hansch, July 25, 1707 in Loemker, p.592-3

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hidden confusedly, as it were, in the chaos of our perceptions. Yet the seeds of the

things we learn are within us [doctrine of Reminiscence] - the ideas and the eternal

truths which arise from them. … Although our mind depends continuously on God in

its existence and action, as does every other creature, I do not think that it needs his

particular concourse over and above the laws of nature for its perceptions, but rather it

deduces its later thoughts from its earlier ones by its internal force and in an order

prescribed by God, as Roelius, whom you quote, rightly says.

The passage raises the question of the relationship of the finite to the infinite, which Nicolaus

of Cusa referred to time and again, which we will discuss further in Chapter 4 “Discovery and

Deduction”. Leibniz also reiterates that human minds can delve into the universe and make

discoveries about it without intervention by God. Rather, minds have their own “internal

force”. The “chaos of our perceptions” implies that our perceptions do not get us very far.

What we “learn” are ideas, and eternal truths arise from those. Clearly, the mind’s access to

what is universal and eternal deserves special consideration. In one of his essays, Leibniz

refers to the mind as the divine in miniature.223 Therefore, it is not surprising that Leibniz is

more Rationalist than Empiricist. He observed that a geometrical argument made in a dream is

as accurate as one made when awake, while a perception in a dream is illusory. Of course, our

perceptions usually dominate our thoughts and there is no thought so abstract that it does not

involve the object of some perception.224 However, just as no-one would deny that air is

essential to life, yet life is something different from and higher than air.

For Leibniz, the nature of transcendental curves is part of the domain of truth, but

transcendental curves are real not only because they or their effects are realisable. Of course,

they are of immediate interest because their effects are real and realisable. As he says, “we

must free the human mind from arbitrary contingencies, in order to bring out the underlying

nature of the thing [the curve] itself.”225 It is difficult to say whether Leibniz would go further

than the structuralist school, which requires a mathematical to be able to manifest in the

physical universe for it to be called real.226 In any case, the point is moot because Leibniz

never spent time on anything for which he could not see significance or repercussions for the

physical universe, or even potential useful to humankind, and regarded such pursuits as a

frivolous waste of time. The point would not be moot if the discussion led to an overturning

of our conception of how God thinks or from where he got the raw ideas from which to design

the universe.

223 Leibniz, G.W. Theodicy §147. There is also an epigraph to Theodicy which says the same, though this author

has been unable to find an edition which includes this epigraph. The epigraph is quoted in Jorgensen, L.M.

“Leibniz’s Theodicy” PHIL 375: Advanced History of Philosophy course notes Fall 2008 p.10 accessed at

http://faculty.valpo.edu/ljorgens/teachres/Theodicy%20Packet.pdf 12 May 2011. Jorgensen states that the

edition being used is an unpublished manuscript of W.H. Warren (trans.), Mulvaney, R.J. (ed.) Leibniz, G.W.

Theodicy. 224 Loemker, p.556 225 Leibniz, G.W. Beaudry, P. (trans.) “The String Whose Curve Is Described by Bending Under Its Own Weight,

and the Remarkable Resources That Can Be Discovered from It by However Many Proportional Means and

Logarithms” Acta Eruditorum, Leipzig, June 1691, last sentence accessed at

http://www.schillerinstitute.org/fid_97-01/011_catenary.html#1 on 9 June 2012 226 See Franklin, J. “Mathematical Necessity and Reality” Australasian Journal of Philosophy Vol. 67 No. 3,

September 1989

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Truths such as the nature of the catenary curve can be discovered systematically. “That is, the

case of developing methods is always more crucial, than particular problems, although it is

the latter which usually bring applause.”227 Further, such methods lead to real benefits. It

extends the science of discovery, “in other words the science of Analysis, which up to now

has been incapable of tackling such questions. Second, it extends the progress of construction

techniques. In point of fact, I have come to realize that the resourcefulness of this curve is

only equal to the simplicity of its construction, which makes it the primary one among all the

transcendental curves.”228

Sense perception and Empiricism

In The Republic, Plato said that all sense perception is opinion and thus is not of great

assistance in discovering truth.229 Leibniz largely concurred. Today, to the layman and

scientist alike, it is common for the testimony of the senses is regarded as the final or, at least,

the most reliable arbiter.

Yet sense perception had already gained primacy through circles associated with Galileo, and

had gained a foothold in the British Isles, especially in the circles of what became the Royal

Society. Fulgenzio Micanzio was the closest friend of Galileo’s patron, Paolo Sarpi. Micanzio

corresponded with William Cavendish the English scientist. Those letters were translated by

the secretary of Francis Bacon, Thomas Hobbes, for wider circulation.230 It is possible that

when Hobbes and Cavendish visited Venice, they met with Sarpi and there is evidence in

Hobbes’ translations that he was familiar with the personality of Sarpi’s personality.231 Sarpi

advocated a presumption that what is perceived with the senses is real, as we will discuss later

in more detail. In fact, Sarpi may have believed that excessive reflection was a weakness and

instinctive action superior leading to the conclusion that in some ways Man is weaker than the

animals which primarily act on instinct based on their sense perception.232 Contrary to these

conclusions reached by Sarpi, he was a regular attendee in meetings of occult circles in

Venice. Giordano Bruno was warmly welcomed by these circles when he was in Venice, and

through this connection Michael White says that Sarpi “knew Bruno well”.233 It would seem

227 Leibniz, G.W., Beaudry, P. (trans.) “The String Whose Curve Is Described by Bending Under Its Own Weight,

and the Remarkable Resources That Can Be Discovered from It by However Many Proportional Means and

Logarithms” Acta Eruditorum, Leipzig, June 1691, second-last paragraph accessed at

http://www.schillerinstitute.org/fid_97-01/011_catenary.html#1 on 9 June 2012 228 Ibid., first paragraph 229 In The Republic (602 d), Plato says, “A stick will look bent if you put it in the water, straight when you take it

out, and deceptive differences of shading can make the same surface seem to the eye concave or convex; and

our minds are clearly liable to all sorts of confusions of this kind.” 230 Malcolm, N. “A summary biography of Hobbes” in Sorell, T. (ed.) The Cambridge Companion to Hobbes

CUP Cambridge 1996, p.22. On the same page, Malcolm speculates that “Hobbes must have gained a special

interest in the writings and political actions of Sarpi, who had defended Venice against the papal interdict of

1606 and developed a strongly anti-papal theory of Church and State”. 231 Kainulainen, J. “Paolo Sarpi between Jean Bodin and Thomas Hobbes: a study on ‘political animal’ in early

modern Europe” Thesis at the European University Institute, Department of History and Civilisation.

Accessed at http://www.eui.eu/Personal/VanGelderen/Theses/JaskaKainulainenThesis.shtml 24 April 2012 232 Ibid. 233 White, M. The Pope and the Heretic: The true story of Giordano Bruno, the Man Who Dared to Defy the

Roman Inquisition Harper Collins 2001, pp.38-39

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that Sarpi was not persuaded by Bruno. Returning to the British Isles, the primacy of sense

perception became much more firmly entrenched after Newton had passed away and the

Royal Society had passed into the hands of its second-generation membership.

Another name of the ideology that places sense perception first is Empiricism or a

posteriorism as against a priorism. Of course, even a priori thinking uses the testimony of the

senses but only to confirm or deny hypotheses formulated by the use of reason.

To maintain that the testimony of the senses is the only thing that has validity in science

removes the role of thought except for undertaking deductive exercises from what is

observed. The dangers of empiricist idealism are pointed out by Franklin and Newstead when

discussing Ormell’s desire to remove indefinable real numbers from mathematics.234 First of

all, what we observe with our senses is subjective. The testimony of one’s own senses can

change; the use of different measuring instruments causes observations to differ.

Observational data requires thought to give it meaning and order; for example, there was

nothing directly discernible in the observational data that Kepler pored over that indicated

elliptical orbits. To give the senses sole authority is also to maintain that the senses are the

only reliable reference in determining what we can be sure of, that is, in determining what we

know. Such authority would be misplaced since, as explained just now, the senses are not

reliable determinants of anything.

As sense perception is mere opinion, to demand that only the senses be relied upon is to desire

that nothing be known. The opponent of this who uses Platonic dialogue to help discover

truth, however, also denies knowability. If there is one thing that Plato succeeds in doing, it is

that answers given always lead to new questions.

Whether we use sense perception or intellectual enquiry, we get nowhere. This catch-22 might

drive anyone with an interest in science to pessimism as to their prospects for success and

depression, for it seems that humans are excluded from science.

Humans are excluded from science in another way. Burtt’s celebrated thesis The Metaphysical

Foundations of Modern Physical Science considered the human-free conception of the

universe adopted by positivist physics. That is, the laws which physics seeks to understand are

unaffected by humans and impact humans only in a physical kinetic sense. This stands in

contrast to the Renaissance view of Dante – for example – that humans are not only part of

Creation but are at its pinnacle. Burtt knew that he did not like the cold Newtonian-Russellian

clockwork universe in which Man is irrelevant, but he purported to supplant it by substituting

an extreme empiricism. That is, Burtt sought to bring Man back into science by declaring that

perceptions of the universe are close enough to reality and therefore should be taken to be

correct, in preference to a mathematical model, say. Burtt seems to think that the only way

234 Franklin, J. and Newstead, A. “On the Reality of the Continuum; Discussion Note: A reply to Ormell,

‘Russell’s Moment of Candour’, Philosophy” Philosophy (published by the Royal Institute of Philosophy) 83

2008 especially p.124. In an earlier article, Franklin discusses the impossibility of the formal sciences were

we to reject imperceptible relations between intangible mathematical objections. Franklin, J. “The Formal

Sciences discover the Philosopher’s Stone” Studies in History and Philosophy of Science Vol. 25 No. 4 1994 ,

p.26 of version at http://www.maths.unsw.edu.au/~jim/philosophersstone.pdf accessed 1 Nov 2010

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humans can be brought back into the universe is through sensory experience, neglecting the

role of mind:235

...the space of perception is too much like the space of real objects to reveal any

essential difference from it. All it needs is to be freed from illusions, private images,

and other experiences lacking social objectivity, to function quite acceptably as real

space. And once this point has been reached there seems no longer any excuse for

maintaining the distinction between sensed qualities and the real characters to which

they correspond.

…

There is simply no science possible of the realm of sensible phenomena unless the

trustworthiness of our immediate perception of spatial directions and relations be

taken for granted.

Not detracting from Burtt’s many and deep insights into the evolution of science, his

empiricist proposal was only possible because he did not give due consideration to the idea of

truth. Leibniz in §§27-29 of The Monadology addressed this directly by contrasting empirics

with reason calling Reason an act of “the rational soul or mind [esprit]” whereas empirics are

a result of perception which even the beasts have.236

As we explained above, to maintain that the senses, including deductions from their

testimony, are the only thing we can be sure of is to say that we can be sure of nothing. To

Cusa, humans could never know the truth as to know it would be to know God and,

metaphorically, such a light would be too bright for any human intellect to gaze upon directly.

Leibniz agreed that there was nothing but a theoretical possibility of anything but that “the

number of all truths which all men together can know is quite mediocre, even if there were an

infinity of men who for all eternity should exalt themselves in the advancement of

sciences.”237

Existence and attainability of truth: Rationalism and Neoplatonism, vs Empiricism

We will refer to promoters of the Primacy of Reason as Rationalists, which is a standard term.

Upon investigations, many Rationalists, up to and including Leibniz, turn out to be

Neoplatonists and vice-versa. The difference between the terms is in their historical baggage

and connotations. Both believe in the primacy of reason, or the inferiority of the senses to the

mind. Now, there are Aristotelian thinkers who give Reason a high position. However, in the

end, the Aristotelian does not give as much primacy as the Neoplatonist, and certainly not

relative to the sense perception, for the Neoplatonist is almost purely Rationalist giving no

value to sense perception except to check the conclusions of Reason.

235 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge and Kegan Paul, London

2nd ed. 1932, reprinted 1950 pp. 315-6 236 Latta, p.233 237 post-1690, Wiener,p.76

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The “new mechanical philosophy” (“NMP”) of the 17th Century, partly due to thinkers like

Kepler, was an understanding that structure was discoverable in the universe, pursuant to the

belief that the universe has a rational design, and its achievements seemed to confirm that the

universe has a rational design. However, the “mechanism” or order is not necessarily

discoverable by sense perception and certainly not by the senses unaided by artificial (human-

made) instruments. Thus, the NMP has its roots in – and so is more closely allied with –

Rationalism and, hence, is closer to Neoplatonism than it is to Empiricism.238

Empiricists clearly differ from Rationalists on the path to truth, though they agree that final

truth – whatever their brand of it might be – is not unattainable by humans. The nature of the

two positions also impacts questions relating to the existence of truth. Cusa regards truth as

having a reality, but considers access to it as being exclusive to God. Humans can make gains

in its direction and approach it, merely. The Empiricist position allows judgement on whether

truth exists at all to be reserved, for the Empiricist does not need to answer the question, even

though an individual Empiricist may accept particular truths.

Empiricism allows – but does not imply – denial of the existence of truth. Once the Empiricist

tries to get into the question, he can only affirm truth’s existence if truth, like observation, is

subjective, which is no truth at all. Burtt made the error of asking what truth is while wearing

an Empiricist hat. The perennial trick of the Empiricist is to not ask the question, and to say

that the question of truth is irrelevant or to say that, as far as they are concerned, what is true

is what we can perceive (see, hear, touch, taste, smell) which can only be an appeal to a

popular kind of commonsense. This approach omits a significant role for the human mind

except in collating and making deductions from observations, which a computer can do quite

well.

If we allow their different conceptions of truth, the Empiricists and Rationalists agree that the

final truth is unattainable by humans. However, there is a key difference. Empiricists say that

all we can know is what the senses tell us, mediated by our prejudices and what we think we

know. Rationalists led by Cusa generally say that we can know what the senses indicate but

we need to understand the very restricted meaning of sensual testimony. However, using our

reason we can come to know what are the causes or causal principles P1 whose effects S1 the

senses detect. By understanding those causes well enough, perhaps we can design and build

an apparatus that allows us to observe them. Thus, through human ingenuity, P1 gives rise to

S2. We now perceive at a deeper level because “higher order” causes have been flushed out to

our senses. In turn, we shall find that sensory effects S2 are caused by principles P2. In

general, our Pn gives rise to Sn+1 through an artificial human intervention to generate the

sensory effect using the principles Pn. In the process of human ingenuity generating Sn+1, it

may also find a method or technique (“C”) of controlling those principles within certain

boundaries, so we get Cn+1 also. In symbols, we could write:

Pn → Sn+1 or Pn → Cn+1

238 This is contrary to the view of Leibniz’s mathematics teacher at the University of Jena, Weigel, who took the

view that the NMP was an extension of Aristotle. See Brown, R. C. Leibniz unpublished, Chapter 4 “A

Young Central European Polymath Between the Scholastics and the Moderns”, p.33 and Mercer, C. Leibniz’s

metaphysics: its origins and development Cambridge University Press 2001

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with each of the arrows representing an active role played by human ingenuity. If observation

were the only capability at our disposal, then neither of these two steps could occur.

This question is all the less frivolous when we note that, for the Empiricists, the causal

connection between the phenomena behind the perception and the perception itself:

Sn = effects(Pn)

is restricted territory in which the human mind has no business because any enquiry in that

domain is pure speculation and perhaps even fantasy. It is difficult to find a pure Empiricist.

For example, Newton, who will be discussed below in more detail, did permit some

consideration of the “effects( )” part of the above formula.

Religious or moral truth vs scientific truth

We now turn to the question of whether religious or moral truth differs from anything

discoverable in science through whatever means. The current Pope suggests that there is no

such difference, while acknowledging that there have been attempts to separate religious faith

from universal truths. In September 2006, Pope Benedict XVI said:239

Dehellenization first emerges in connection with the postulates of the Reformation in

the sixteenth century. Looking at the tradition of scholastic theology, the Reformers

thought they were confronted with a faith system totally conditioned by philosophy,

that is to say an articulation of the faith based on an alien system of thought. As a

result, faith no longer appeared as a living historical Word but as one element of an

overarching philosophical system. The principle of sola scriptura, on the other hand,

sought faith in its pure, primordial form, as originally found in the biblical Word.

Metaphysics appeared as a premise derived from another source, from which faith had

to be liberated in order to become once more fully itself. When Kant stated that he

needed to set thinking aside in order to make room for faith, he carried this programme

forward with a radicalism that the Reformers could never have foreseen. He thus

anchored faith exclusively in practical reason, denying it access to reality as a whole.

Similarly, Leibniz stated that truth must be consistent across all domains. In particular, he

included the toughest example of science and religion, saying that we should not accept for

religion what we would not accept in science. He was not referring to a standard of proof but

was saying that the actual content of ideas and doctrine should be consistent across science

and religion.

239 Papal Speech, Apostolic Journey of His Holiness Benedict XVI to München, Altotting and Regensburg 9-14

September 2006, Meeting with the representatives of science, Lecture of the Holy Father, Aula Magna of the

University of Regensburg 12 September 2006 “Faith, Reason and the University: Memories and Reflections”

accessed at http://www.vatican.va/holy_father/benedict_xvi/speeches/2006/september/documents/hf_ben-

xvi_spe_20060912_university-regensburg_en.html 1 May 2009

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Neoplatonism, Empiricism and Atheism

The scientific work of Kepler and Cusa was bound up with their theology; any inconsistency

between science and theology was anathema to them. Indeed, there was not really any

separation between the two for the discoveries of science were but a manifestation of true

theology. They would have been forced to revise their science or theology or both were an

inconsistency to arise; at least, they would have known that one or the other or both must be

wrong.

The Empiricist position neither confirms nor denies the existence of God. Thus, the Empiricist

is free to choose on the basis of personal preference whether or not they believe in the

existence of God.240 It might not be a coincidence that Empiricism was promoted by Venetian

gentlemen, such as Paolo Sarpi, Galileo’s patron, who were also inclined towards Atheism.

The consummate Neoplatonist is an a priorist who strives for a “God’s eye view”. That

Neoplatonist assumes his latest and best version of the “God’s eye view” in formulating

hypotheses within that pan-Creation context.

Many in the Empiricist school, even today, not only deny the necessity of a God or Creator in

science, but also deny that metaphysics has any relevance to science and some even claim that

metaphysics is meaningless word play.241 This is in itself a kind of metaphysics though its

advocates refuse to label it so. To say that science is the study of things that can be observed

and that nothing outside of the field of observation is a valid domain of enquiry at its simplest

level denies the validity of any metaphysical enquiry. How does one justify this position

without something like a metaphysical argument? Burtt points out that an attempt to exclude

metaphysics and not hold any metaphysical position itself carries a raft of embarrassing

metaphysical assumptions.

If sensory observation is all that we have, then we can only be aware of correlations and

coincidence of events. No pan-Creation view is possible; it would not make sense to ask what

is happening on the other side of the universe. Thus, the Empiricists differ from the

Rationalists in the nature of truth. For the former, truth is an ever-expanding basket of

correlations. Ultimate truth is all the correlations that exist. For the latter, truth is a principle

which is implied and necessarily so in the context of philosophy, metaphysics and theology. If

it is a principle of natural science, then it must have been confirmed by experiment whether

by direct observation or by deduction or calculation from observations. Ultimate truth is the

mind of God or the Creator of the universe.

Atheists had fewer difficulties in adopting an Empiricist outlook. The theology of Cusa and

Kepler did not permit an Empiricist outlook. However, even though the British Royal Society

240 By adopting the “practical reason” of the Empiricist, Kant declared that he needed to set thinking aside in

order to make room for faith. Kant is beyond the scope of this dissertation. However, we are here nudging up

against Pope Benedict XVI’s objection to Kant’s outlook on faith. Ibid. 241 For example, this is precisely the outlook of Ian Bryce who is on the executive committee of the Humanist

Society and is the founder of the Australian Secular Party. From conversation with Dr Ian Bryce of the NSW

Humanist Society at Eastside Radio 89.7 FM studio in Paddington on Friday 5 Feb 2010

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was generally Empiricist in its orientation, British thinkers such as Henry More, Robert Boyle

and Isaac Newton spent some effort in ensuring that their scientific outlook had some basis in

a theology they could believe in. Indeed, Newton wrote, “One principle in Philosophy is the

being of a God or Spirit infinite eternal omniscient omnipotent.”242 However, McGuire also

explains that the meaning Newton ascribes to the term “principle” in this context is different

from when he uses the term as having implications or repercussions for science.243 Boyle in

particular drew inspiration for his belief in God from his scientific insights though in a rather

gnostic way seeing the universe as divinely animated. Leibniz regarded a universe of that kind

as imperfect – and therefore impossible – because it would require ongoing participation by

its Creator. So “there is no soul of the universe” and “I hold … the hylarchic principle of

Henry More, as being either impossible or superfluous; and it is enough for me that the

mechanism of things [the universe] is constructed with so much wisdom that all these marvels

come to pass through its very development, organised beings being evolved, I think,

according to a preconceived plan.”244 Leibniz explained that he did not think that proponents

of the hylarchic principle had a distinct idea of their conception.245

Summary of the ’isms

We are now considering the converse of the earlier discussion on Empiricism neither

confirming nor denying Theism. Assuming the theology of Kepler and Leibniz, say, we have

said enough to formulate this summary:

Theism ==> ¬ Empiricism

Empiricism =/=> Theism

Empiricism =/=> ¬ Theism

Theism ==> Rationalism246

Rationalism ==> Theism

The diagram becomes more complicated when we consider different kinds of Theism, i.e.

different theologies. It would be interesting to consider the God of Newton, and how it differs

from the God of Neoplatonists such as Kepler. For example, is it hylarchic like the God of

Henry More? That discussion is beyond the scope of this thesis.

Conclusion

We have situated the idea of truth in each of the Rationalist, Neoplatonist and Empiricist

schools. Those of the Rationalist and Neoplatonist orientations (which are often found

together in any given thinker) have a better structured conception of the existence and

attainability of truth. This might be a result of their Theism. Empiricism does not necessitate a

242 McGuire, J.E. “Newton’s ‘Principles of Philosophy’: An intended preface for the 1704 Opticks and a related

draft fragment” The British Journal for the History of Science 1970 vol. 5 no. 2 pp. 178-186, at p.183 243 Ibid., p.180 244 1698, Wiener pp.138-9 245 “Reflections on the doctrine of a single universal spirit” 1702, Loemker, p.555 246 c.f. Wiener p.292 that God’s justice is not arbitrary, that God governs Himself by reason

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developed conception of a Creator or the Creator’s relationship to the physical universe and

so does not derive clarity on the whole of Creation as a single conception that the Rationalist

and Neoplatonist do. We do not say that such clarity would be impossible for an Empiricist to

attain. However, it would only be possible after further development of ideas that can only

arise from Rationalism and Neoplatonism which are not as tightly bound by the constraints of

sense perception or sense perception enhanced by scientific instruments. To be sure,

understanding how the Creator thinks is not easy but in making the attempt leaps of

understanding can occur. This sets forth the situation as it was until the early 18th Century.

Whether the attempt to understand how the Creator thinks is also required today may require

further enquiry. However, since the considerations and principles raised in this chapter are

universal and timeless, we would expect the same conclusions.

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Chapter 5: The Neoplatonist and Empiricist schools

Introduction

In the previous chapter, the understanding that structure is discoverable in the universe was

discussed. It was called the “new mechanical philosophy” (“NMP”) though it was often

anything but “mechanical” in the modern sense. Indeed, Kepler epitomized the origins of

NMP and his search, indeed expectation, was to find harmony and beauty in the structure of

the universe. Leibniz was a continuation of this new mechanical philosophy. Today, the idea

that the universe has a rational design is associated with physical experiments and observable

evidence in the tradition of Baconian Empiricism. On the other hand, Neoplatonism is

regarded as a mystical quasi-religious movement that lacks scientific credibility. The

orientation and methods of Neoplatonism were not always regarded in this way before

Leibniz. It was in Leibniz’s lifetime that the lines between Neoplatonism and Empiricism

started to be drawn. Leibniz adopted many of the methods of Neoplatonism but certainly

accepted the importance of experiment. In effect, Leibniz saw the pendulum swinging too far

towards what experiments can indicate to the senses, rather than using intellectual tools

informed but not dominated by observations. Because Leibniz saw the fork in the road and

made his position clear, much can be learned about Leibniz by considering the Neoplatonist

and Empiricist orientations and Leibniz’s relationship to them.

The reality and intellectual accessibility of concepts and “things” in a non-visible domain is

the nub of many debates between Neoplatonists and non-Neoplatonists. Concepts such as the

infinite exemplify what is unobservable. Friedrich Schiller (1709-1805) is one of Germany’s

most famous poets and playwrights. Schiller took the idea of the infinite seriously, and we

begin the chapter with Schiller’s thoughts on the topic as an example of the accessibility of

metaphysical ideas. Leibniz regarded mathematics as a subdomain of a domain of calculation

on metaphysical concepts. Any domain of mathematics that relies on the infinitesimal

presents itself as an example. To the layman, it might be paradoxical that “medieval

speculations” were instrumental in bringing about the concept of the infinitesimal used by

Barrow, Leibniz and Newton in their respective and evolving versions of the calculus.

As far as calculations of any kind go, they are tedious when they represent stepwise reasoning

using symbols to ensure precision. Leibniz saw the limitations and understood that such a

mode of reasoning was retarding the development of physics and engineering, because

available mathematical tools were time-consuming to use. Leibniz made reference to his idea

for a Universal Characteristic to help mathematics escape its limitations, but left it to future

generations to further build the idea on which he placed so much hope. Leibniz also short-

circuited stepwise reasoning with his maxim that perfect knowledge of a domain requires us

to see the whole in a single act of the mind or in a single thought.247 From there, one can lever

up to a higher conception that subsumes and transcends the existing understanding in a single

bound.

247 Wiener pp.77-78

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The distinguishing features of Neoplatonism have not been mainstream since the 17th Century.

Further, significant developments are rare adding to the obscurity. It is true that forming

hypotheses is a distinguishing feature of Neoplatonism. However, Neoplatonists tend to

hypothesise based on their conception of the Creator’s mind in relation to the entire universe,

rather than on considerations attained through observation alone. Once an initial hypothesis is

formed and work to verify it begins, the process of observation, calculation and number-

crunching is indistinguishable from any other mode of science. Thus, the Neoplatonic

scientist must be as concerned about precision as any other scientist. We will discuss Kepler

and his Neoplatonist orientation. Franklin notes that Kepler’s refusal to compromise with

precision is as impressive as that of any scientist of his age and perhaps ours.248

The rest of the chapter will be spent discussing the development of the Empiricist school prior

to Leibniz’s lifetime. The British Royal Society typifies the Empiricist school today but we

argue that this is not where Empiricism began. The ideological takeover of the University of

Padua – which was once a centre of Neoplatonism – by Averroism may have been

instrumental in nurturing the early stages of what became the “Empiricist revolution”.249

However, we will not go back that far. We start with Paolo Sarpi of Venice, a contemporary of

Galileo, though 10 years elder to Galileo. England was heavily influenced by Italy, and it was

standard for the scions of wealthy English families to undertake a “grand tour” of the

Continent including Italy and especially Venice. Sarpi’s writings were often translated into

English and published in England, though we have no evidence of how widely read they

were. We discuss how Sarpi’s atheism was naturally allied to his tendency to Empiricism.

Empiricism leads to rigorous deductivism, hence the double-barrelled term “empirico-logic”.

Any discussion of influences on science in the British Isles in that period leads to Newton, so

we will discuss Mamiani’s discovery of the close parallel between Newton’s prescribed

method of discovery and a standard logic text of the period. Newton’s opposition to forming

hypotheses is a natural part of an empirico-logical stance, but it contrasts with the approach of

Neoplatonic scientists like Kepler.

Next, we shall discuss the consequences of mandating empirico-logic as a scientific method.

There were members of the Republic of Letters who criticised Leibniz’s calculus on the

grounds that it lacked precision. Leibniz openly disagreed with them and used the label

“rigorists” for such writers. However, the fact that there were such critics is not surprising

248 Franklin, J. The Science of Conjecture: Evidence and probability before Pascal J. H. Press Baltimore and

London 2002, pp.150-1 249 “In the course of the 14th Century, European primacy in Averroan studies passed from the University of Paris

… to the great Italian schools: Bologna and especially Padua.” Carboni, S. Venice and the Islamic world,

828-1797 Yale Univesity Press 2007 p.153. The influence of Padua on English intellectual life is explained in

Woolfson, J. Padua and the Tudors: English students in Italy, 1485-1603 University of Toronto Press 1998. A

Princeton University webpage for second year undergraduate history says, “The University of Padua was one

of the most prominent universities in early modern Europe, known particularly for the rigor of its

Aristotelean logic and science.” accessed at http://www.princeton.edu/~his291/Padua.html 10 May 2011

While Thomas Aquinas would disagree with Averroes calling himself an Aristotelean, Averroan studies are

regarded as a development of Aristotelean logic, and Averroes was regarded as a Neo-Aristotelean.

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given the dominance of Averroism in such eminent institutions as the University of Padua.

Finally, we close with a couple of open questions that would benefit from future research.

Schiller and the infinite

Friedrich von Schiller (1759 – 1805) is one of Germany’s most famous poets and playwrights.

Seventy-seven years after Leibniz’s death, Friedrich Schiller distinguished the logical

estimation of magnitude from the aesthetic.250 Estimating a magnitude in a “logical fashion”

is to relate it to the “cognitive faculty”, experience something about the object and behold

something outside oneself. To estimate something aesthetically is to relate it to the faculty of

“sensibility”. Contrary to the logical fashion, in aesthetic estimation one experiences

something within themselves caused by the imagined magnitude of the object. In this case, the

thinker is neither measuring nor estimating magnitude, but themselves become for the

moment an infinite magnitude to themselves. Schiller writes that anything that evokes the

(intellectual) experience of being an infinite magnitude to the intellect is sublime.251

Schiller’s distinction between logical versus aesthetic estimation is the same as that between

logical deduction and Neoplatonic reasoning. This “aesthetic” is not merely a quality of being

subjectively pleasing to the mind, but is a universal quality. While Schiller uses the concept of

the infinite with in the individual thinker as the yardstick, Schiller’s central point is that that

measure is itself universal.252 While Schiller did not use the term “Neoplatonic”, the

Neoplatonist encourages abstraction “in the sphere of the infinite”.253 This is the sphere of

truth, whether it is classified as metaphysical, mathematical, moral, artistic, musical or

otherwise; after all, these are human categories and Schiller would argue that truth does not

know the separations between these categories. The corporeal human condition inevitably

“resumes her rights to give an imperious reality to our existence, to give it contents,

substance, knowledge, and an aim for our activity.” This “concretisation” of

realisations/discoveries brings new understanding out of the domain of the infinite and into

the temporal; the result cannot be universal or eternal though it may be useful for a few

centuries or millenia.

The Neoplatonist acknowledges that the domain of the infinite is accessible to the human

mind. The Neoplatonist goes further and, like Schiller, says that discoveries are only worthy

of the name if they do pluck something new from that domain. Such a discovery is generally

useful to the bulk of humankind precisely because it brings a new principle into the corporeal

domain where “the rest of us” can work with it.

250 Friedrich Schiller, Johnson, S. trans. Of the Aesthetic Estimation of Magnitude (1793) Accessed at

http://www.schillerinstitute.org/transl/Schiller_essays/magnitude.html 1 Jan 2011 251 Schiller was responding to Kant’s The Critique of Pure Reason first published 12 years before Schiller’s

essay. Accessed at http://www.gutenberg.org/cache/epub/4280/pg4280.html 1 Jan 2011 252 Schiller uses this to posit a universal and objective quality of beauty which is equated to absolute truth, in

opposition to Kant’s position that beauty is subjective. In Schiller’s Letter XII, he refers to a “unity of idea”

according to which “We are no longer individuals but a species”. See next footnote. 253 Friedrich Schiller, edited by Riikonen, T. and Widger, D. Aesthetical and Philosophical Essays, Letter XII

Accessed at http://www.gutenberg.org/files/6798/6798-h/6798-h.htm on 1 Jan 2011

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Metaphysical calculations and a method of Analysis for concepts in physics

The calculus is founded on the concept of the infinitesimal which might have an ontological

reality but has no physical reality. Therefore, the calculus is a tool of precision in metaphysics

before it is a mathematical tool. We may call it a mathematical tool because it brings ideas

from the metaphysical domain into a form which humans, or computers, can systematically

work with. However, the crux of the calculus is metaphysical before anything else. It is also

outside the domain of any possible empirical enquiry, for it allows the expression of a

principle about a curve which cannot be seen from the curve itself. It embodies the idea of a

hidden underlying principle and provides a method for dealing with such principles in a

systematic way. Today, we take the idea of instantaneous rates of change and all that flows

from them for granted, but in Leibniz’s time none of it was obvious.

Leibniz regards the relations of forms and abstract quantities as belonging to Metaphysics,

which can be structured into a calculus or Universal Characteristic. He regards Combinatorial

Science as an application of such Universal Characteristic. In turn, he says “all of Algebra is

merely an application of a Combinatorial Science of quantities.”254 According to Leibniz,

Algebra is a particular class of methods of calculation within Metaphysics.255

If Algebra is just a subdomain of a subdomain of Metaphysics, and if all of Metaphysics is

subject to structured Analysis, we would expect physics – a consequence of Metaphysics – to

be subject – or at least amenable – to structured (a priori) reasoning. We will see below that

this is exactly what Leibniz believed. It is not surprising that Leibniz placed experiment a

long way below Reason in importance.

Decades before Leibniz was born, Tycho Brahe and Johannes Kepler had done significant

work with mathematics in the sense of “number-crunching” to test hypotheses. We know that

Kepler was as ambivalent as Leibniz about the infallibility or ultimacy of mathematical

methods; that is, Kepler did not come close to claiming that the entire universe could be

reduced to, or understood via, mathematical calculation. For Leibniz, the domain of structured

Reasoning was much broader than mathematics. Leibniz says that “there is an art of Analysis

which is more inclusive than Mathematics” and that he has a proof that such an art or method

exists.256 This method turns out to be a framework for reasoning about matters metaphysical

and physical based on premises which are, at least in part, a result of a priori metaphysical

thought.

254 Wiener, p.210 255 It is this distinction between mathematics and a more general Analysis that Johnson does not recognise.

Johnson seems to think that where the usefulness of Mathematics ends for Leibniz, experiment begins.

However, for Leibniz, mathematics is only one of many tools for Analysis. In turn, Analysis is one of many

modes of human Reason. Johnson, A. H. “Leibniz’s method and the basis of his metaphysics” Philosophy

1960 vol. 35, 51-61. See page 54. 256 1715, Wiener, p.201

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Invaluable medieval speculations

Prior to Brahe and Kepler, Boyer says that the medieval period added little to the classical

Greek works in geometry or algebra. Rather, it contributed, chiefly, “speculations, largely

from the philosophical point of view, on the infinite, infinitesimal, and continuity” as well as

“new points of view with reference to the study of motion and variability. Such disquisitions

were to play a not insignificant part in the development of the methods and concepts of the

calculus”.257

One of the most significant of the “medieval speculators” was Nicolaus of Cusa of whom

Kepler was a disciple although a century separated them. “The fullest expression of Nicolaus

of Cusa’s mathematical thoughts on the infinite and the infinitesimal, however, are found in

the work of Johannes Kepler, who was strongly influenced by the cardinal’s ideas … and who

was likewise deeply imbued with Platonic and Pythagorean mysticism. It was probably the

imaginative use by Cusa of the concept of infinity which led Kepler to his principle of

continuity.”258 Kepler wrote of Cusa others divinus mihi Cusanus, i.e. “Cusa and others seem

to me divine” in drawing the analogy of the circle compared with polygon to God compared

with his creatures.259 It was Cusa, says Boyer – albeit himself rigorist in his sympathies – who

led Kepler to include normal and limiting forms of curves under a single definition of

continuity encompassing conic sections as a single family of curves.260

Leibniz saw the need for more powerful methods

To Leibniz, mathematics was the art of reasoning using symbols to represent quantities.

Symbols could be used for many other purposes.261 Leibniz’s recognition that attention to

detail sufficed for calculations to be carried out indicates that he did not think particularly

highly of the creative or intellectual content of the calculation process.262 “For it is unworthy

of excellent men to lose hours like slaves in the labour of calculation which would safely be

relegated to anyone else if machines were used.”263 Rather, the real achievement was in

257 Boyer, C. The History of the Calculus and its Conceptual Development Dover Publications, New York 1949,

p.94 258 Ibid., p.93 259 Duncan, A.M. (trans.) Kepler, J. Mysterium Cosmographicum Abaris Books, Janus Series Norwalk USA

1981, Chapter II “Outlines of the primary derivation” p.93 260 Boyer quotes from Kepler’s Opera omnia II 595, translated from the quoted Latin by this author, “we find

that a straight line is an hyperbola obtuse in the extreme. And from Cusanus we learn that a circle is an

infinite linear thing. They are several things simultaneously, not discrete alternatives, whose different faces

are turned to light by the use of analogy.” Ibid. 261 post-1690 in Wiener, pp.74-5 262 This is pretty close to the heart of Leibniz’s critique of Descartes’ subjectivism. Quite simply, “Yes, humans

make mistakes, but that does not mean that reality is subjective.” As Raynaud wrote, “Methodological doubt

[for Leibniz] does not have the weight which Descartes accords to it.” in McCarthy 1998, p.152 referring to

Leibniz’s response to Article 5 of Descartes’ Principles of Philosophy. This response by Leibniz is in

Loemker 1969, p.384 263 Leibniz, G.W. 1685 “Machina arithmetica in qua non additio tantum et subtractio sed et multiplicatio nullo,

divisio vero paene nullo animi labore peragantur” Kormes, M. (trans.) “Leibniz on his calculating machine”

in Smith, D. E. A Source Book in Mathematics Dover Publications, Mineola N.Y. 1959 (first published by

McGraw-Hill 1929), p.181

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devising the systems and methods for calculation, which could then be exercised in a

relatively straightforward way and perhaps even automated in the future. Leibniz had made a

contribution to such automation by designing the “Step Reckoner” calculating machine in

1671 which was built in 1673.264

Reason gives value to observations

Without effective reasoning, even plentiful observations are worth little.265 Thus, Leibniz saw

the need for an ability to comprehend “the whole” with mathematical precision in order to

derive advantage from new observational technologies. Leibniz wrote:266

I have no hope that we can get very far in physics until we have found some such

method of abridgement to lighten its burden of imagination. For example, we see that

a series of geometrical reasoning is necessary merely to explain the rainbow, one of

the simplest effects of nature; so we can infer what a chain of conclusions would be

necessary to penetrate into the inner nature of complex effects whose structure is so

subtle that the microscope, which can reveal more than the hundred-thousandth part,267

does not explain it enough to help us much. Yet there would be some hope of

achieving this goal, at least in part, if this truly geometrical analysis were established.

Leibniz is referring to the absence of a tool that would allow us to calculate the inner

workings of nature. For Leibniz, too much imagination is required and far too many detailed

experiments. Since nature was constructed rationally, such a tool must be available. This

returns us to Leibniz’s high hopes for the concept of the Universal Characteristic. The idea is

that all concepts in science are representable by symbols which can then be manipulated to

locate new truths.268 The use of symbols helps enforce precision. “[T]he best advantage of

algebra are only samples of the art of characters whose use is not limited to numbers or

magnitudes.”269 It is clear that the emphasis is on introducing precision and adding tools to the

arsenal of methods available to the reasoning process. Leibniz’s Universal Characteristic

might today go some way towards “a unified theory that covers mathematics, pure and

applied, as well as the formal sciences.”270

264 Leibnitia webpage http://www.gwleibniz.com/calculator/calculator.html accessed 7 August 2010. At the IBM

Archives it is described as “a major advance in mechanical calculating. The Leibniz calculator incorporated a

new mechanical feature, the stepped drum — a cylinder bearing nine teeth of different lengths which increase

in equal amounts around the drum. Although the Leibniz calculator was not developed for commercial

production, the stepped drum principle survived for 300 years and was used in many later calculating

systems. ” http://www-03.ibm.com/ibm/history/exhibits/attic3/attic3_037.html accessed 7 August 2010 265 Wiener, last para. p. xxiii and first para. p.xxiv. Also Book IV, Chapter XII, §13 New Essays on Human

Understanding in Wiener, p.479 266 Loemker, p.250 (Letter to Huygens, 1679 around two years after Leibniz’s initiation into Huygens’

experiments with the [French] Royal Academy of Sciences) 267 The microscope was central to the work of Hooke in his role as demonstrator at the British Royal Society.

Arnol’d, V.I. Huygens and Barrow, Newton and Hooke Birkhauser Verlag, Basel 1990, pp.11-14. 268 Wiener, pp. 73-4 269 Ibid., p.74 270 Franklin, J. “The Formal Sciences discover the Philosopher’s Stone” Studies in History and Philosophy of

Science Vol. 25 No. 4 1994 pp.513-533, p.25 of online pdf

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Leibniz affirmed that ultimately the universe could be explained through analytical methods

of some kind.271 Yet Leibniz saw too great store being set by formal reasoning using the

inadequate tools of logic which were then available. Penetrating the “inner nature of complex

effects whose structure is so subtle that the microscope, which can reveal more than the

hundred-thousandth part, does not explain it enough to help us much” would require

something far more powerful than the syllogism. Indeed, it might need to be a “truly

geometric analysis”. These cumbersome methods were represented by the positivism through

formalist logic which had been gaining primacy since Averroes in the 12th Century.272 Thomas

Aquinas wrote a critique of Averroes’ interpretation of Aristotle, disputing metaphysical

fundamentals such as the relationship between the intellect and the soul rather than logical

methods. Whether Averroes sought to expound on Aristotle faithfully or whether he

deliberately added a little too much positivism of his own is beyond the scope of this thesis.

That mathematics is an indispensable tool in science is self-evident to 21st Century readers.

But if we are saying that some mathematical tools are really just a kind of metaphysics, then

more explanation is needed.

The prevailing view that science stands independent of metaphysics contrasts with the outlook

of Leibniz and his forebears in the Humanist Renaissance. For Leibniz, science as it is done

by humans is a temporary understanding to be replaced by a future, richer understanding.273

This is somewhat like Cusa’s doctrine of docta ignorantia or “learned ignorance”. Physical

phenomena are a manifestation of an underlying metaphysical reality that is dynamically in

progress, and is only discoverable by the mind. What is the nature of the underlying

metaphysical reality? We will never know it completely, but the little we can know about its

abiding nature flows from our reasoning about God and God’s expression in Creation. Thus,

the Neoplatonic scientist necessarily is an a priorist.

This thesis is not alone in pointing out and supporting Leibniz’s preference for a priori

explanation merely provides description. In the science of motion, Leibniz regarded rational

analysis as superior to experiment. Indeed, “experiment must be eliminated from the science

of the abstract reasons for motion, just as they should be eliminated from geometrical

reasonings. For they are demonstrated not from fact and sense, but from the definition of the

271 “nor do I know why you should consider as most absurd the view that everything happens mechanically in

nature, that is, according to certain mathematical laws prescribed by God.” Leibniz, G. W. “Letter to Herman

Conring” 19 March 1678, in Loemker, L. G. W. Leibniz Philosophical Papers and Letters 2nd ed. Reidel

Publishing Company 1969, p.189 272 Petrarca was an outspoken and influential critic of Averroism as well as of stepwise reasoning as practised

under the heading of “dialectic”. Petrarca “On his own ignorance and that of many others” c.1368, pp.47-133

in Cassirer, E., Kristeller, P. O., Randall, J. H. Jr (eds and trans.) The Renaissance Philosophy of Man

Phoenix Books, University of Chicago Press 1948 and Brand, P. Cambridge History of Italian Literature

Cambridge University Press 1999, p.134. Cusa continues Petrarca’s programme of demonstrating that

intellect as exercised by an intelligent commoner can be more effective than the formal reasoning promoted

by the scholastics.. 273 Post-1690 “On the horizon of human doctrine”, Wiener pp.76-77

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terms.”274 Brown mentions this without criticism. Indeed, he calls Leibniz’s quasi-a priori

explanation of elasticity in collisions ingenious.275

Kepler, Neoplatonism and precision

Much of this was said by Kepler in his introduction to Mysterium Cosmographicum in which

his statements on science make it clear that he is the consummate Neoplatonist. Neoplatonism

is – among other things – a mindset, and there were areas with greater concentrations of

“practitioners” and sympathisers than others. Burtt tells us that Copernicus sought the

“southern” intellectual influences.276 Perhaps this was because he was already interested in

the Neoplatonic outlook which had many adherents in that region of Europe.

There is a misconception that Pythagoreanism and Neoplatonism are synonymous with

mysticism, particular interpretations of Cabala and occult sects.277 There may have been such

offshoots, but as far as leading Neoplatonists from the 15th Century onwards are concerned,

nothing could be less correct. Their theology caused them to shun “mystical arts” as sophistry

at best and Satanic at worst.278

Copernicus himself was decisively Neoplatonic.279 In the decades after Copernicus lived, it

was only arch Neoplatonists who carried his standard. An example is Giordano Bruno whom

no-one could disagree was an arch Neoplatonist:280

In his work The Ash Wednesday Supper, a story of a private dinner, being entertained

by English guests, Bruno spreads the Copernican doctrine. A new astronomy had been

offered the world at which people were laughing heartily, because it was at variance

with the teachings of Aristotle. Bruno was carrying on a spirited propaganda in a

274 From a preliminary study towards his Theoria Motus Abstracti. Leibniz, G.W. Sämtliche Schriften und Briefe

Deutsche Akademie der Wissenschaften zu Berlin (eds) Akademie-Verlag, Berlin, 1923 Series 6, volume 1,

p.160, translated in Garber, D. Leibniz: body, substance, monad Oxford University Press 2009, p.15 275 Brown, R. C. Leibniz unpublished, Chapter 4 “A Young Central European Polymath Between the Scholastics

and the Moderns”, pp.41-42 276 Burtt, Chapter II “Copernicus and Kepler” p.22ff 277 Stuart Brown addresses this misconception. Brown, S. “Leibniz and Berkeley: Platonic Metaphysics and ‘The

Mechanical Philosophy’” Chapter 16 in Platonism at the Origins of Modernity: Studies on Platonism and

Early Modern Philosophy Springer 2008, pp.239-253. Edward Rosen’s writing has done something to help

perpetuate the misconception. See Rosen, E. “Was Copernicus a Neoplatonist?” Journal of the History of

Ideas Vol.44, No.4 (Oct-Dec 1993), pp.667-9. Rosen’s argument that Copernicus was not a Neoplatonist is

based on the misconception of Neoplatonism as a mystical doctrine that “all reality has its source in the

transcendent One, which produces a series of less unified levels of being, down to the last and lowest, the

physical universe, a living creature endowed with a divine soul; at our highest, we humans can join the One

in a mystical union.” This sounds more like the doctrine taught in a New Age yoga class. We wonder whether

Rosen merely has an innocent misconception, because apparent bias – not only against Plato but against

Christianity – is reflected by his opening sentence, “Christian thought was profoundly influenced by the

ancient pagan Greek philosopher Plato.” 278 Leibniz wrote, “There are some who imagine a world of light in their brains.” However, “this is not the light

but only a heating of their blood.” Loemker p.367. Also see “On the general characteristic” in Loemker 1969,

p.221. 279 Kuhn, T. S. The Copernican Revolution Harvard University Press 1957 280 Kessler, J. J. PhD “Giordano Bruno: The Forgotten Philosopher” accessed at

http://www.infidels.org/library/historical/john_kessler/giordano_bruno.html 10 May 2011

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fighting mood. Between the year[s] 1582 and 1592 there was hardly a teacher in

Europe who was persistently, openly and actively spreading the news about the

‘universe which Copernicus had charted’, except Giordano Bruno.

How could a work so precise and ultimately so successful in describing physical phenomena

as that of Copernicus have been carried out by a Neoplatonist? This question only needs to be

asked if one has a preconception that Neoplatonism is a mystical and “unscientific” set of

doctrines. It would make no sense to even ask whether precision and calculation figures in

such a set of doctrines.281 As mentioned, this is a misconception.

The need for exactness is outlined by Burtt:282

As with Kepler, so with Galileo, this mathematical explanation of nature must be in

exact terms; it is no vague Pythagorean mysticism that the founder of dynamics has in

mind.

As an aside, Leibniz addressed this directly in c.1679, “Men have been convinced ever since

Pythagoras that the deepest mysteries lie concealed in numbers. It is possible that Pythagoras

brought over this opinion, like many others, from the Orient to Greece. But, because the true

key to the mystery was unknown, more inquisitive minds fell into futilities and superstitions,

from which there finally arose a kind of popular Cabala, far removed from the true one, and

that multitude of follies which is falsely called a kind of magic and with which books have

been filled.”283 This confirms Stuart Brown’s analysis in that Leibniz attacks what are

popularly – but incorrectly – thought to be elements of Platonism even today.

Galileo says that the peripatetics, especially, have written great volumes on the problem of

falling bodies and yet have never made their understanding exact. Indeed, the idea that

quantification is the only way of defining a phenomenon precisely is Neoplatonic. This is not

surprising considering that the reality of numbers was maintained by the Pythagoreans against

opposition. Thus, the idea of measurement ultimately is Neoplatonic.284 Galileo himself, a

pioneer of precise experimental physics and who is not normally classified as a Neoplatonist,

is said to have been “supported by the onrushing Pythagorean tide”.285,286 Leibniz’s search for

precision and the idea of a Universal Characteristic for precise and systematic reasoning is

consistent with this.

281 Rosen, E. “Was Copernicus a Neoplatonist?” Journal of the History of Ideas Vol.44, No.4 (Oct-Dec 1993),

pp.667-669 282 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, p.70 283 “On the general characteristic” in Loemker , L. E. Gottfried Wilhelm Leibniz: Philosophical Papers and

Letters 2nd ed. D. Reidel, Dordrecht Holland 1969 1969, p.221 284 Hence, today’s heavily quantitative society and culture reflect a heavy influence of Neoplatonism in our

heritage. 285 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, p.197 286 Galileo’s debt to Pythagoreanism is explained in Demarco, D. “The dispute between Galileo and the Catholic

Church” Homiletic and Pastoral Review 2002 accessed at

http://www.catholiceducation.org/articles/science/sc0043.htm 26 May 2011

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The Empiricist school and the influence of Paolo Sarpi

Paradoxically, it is with the non-supporters of Renaissance Neoplatonism that precision and

numerical methods are usually associated – that is, with the Empiricists. We introduce Paolo

Sarpi, Chief Theologian to the Republic of Venice. Paolo Sarpi is an example of the

importance of the intentional view of history: that it is difficult or impossible to make sense of

historical processes and the decisions of historical figures without having some grasp of their

intentions and the intentions of the cultural and political framework in whose thrall they

acted.

Contrasting with Kepler, in Sarpi’s statements on science he declares himself a pure

Empiricist. Sarpi sat at the centre of a network of influence with the blessing of the Republic

of Venice whose power was waning but which was a significant financial and political force

in Europe.

Sarpi and Galileo

Galileo was personally close to both Kepler and Sarpi. Galileo was friends with Kepler as a

student and they continued their correspondence following graduation. Eventually, Sarpi

became Galileo’s friend and patron.287 Rather than being a disinterested source of funds for

budding scientists, Sarpi had his own philosophy of science and made a clear statement which

sounds a little like Newton who was not to enter the scene until nearly 75 years later. Sarpi

says that potentially there are four possible ways of gaining new knowledge:

1. pure reason

2. pure perception

3. perception followed by reason

4. reason followed by perception.288

Sarpi rejects 1 (pure reason) as pure speculation/fantasy. He rejects 2 (pure perception) as

preventing the obtaining of meaning. He rejects 4 (reason followed by perception) as

prejudicing perception with advance speculation based on air. Kepler addressed option 4 by

saying that hypotheses should not be formulated by idle speculation. Meli explains that

Kepler imposed constrains on how hypotheses are formed. In Epitome Astronomie

Copernicae Kepler wrote, “astronomers should not have absolute freedom to think up

anything they please without reason; on the contrary, you should give causae probabiles for

your hypotheses which you propose as the true cause of the appearances, and thus establish in

advance the principles of your astronomy in a higher science, namely physics or

metaphysics.”289

287 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, Chapter III “Galileo” p.63 and Robertson, A. Fra Paolo Sarpi: The Greatest of the Venetians

George Allen & Company, London 1911, pp.73-75 288 Wootton, D. quoting from Sarpi’s Pensiero no.146 in Paolo Sarpi: Between Renaissance and Enlightenment

Cambridge University Press, 2002, p.37 289 Quoted in Meli, D.B. Equivalence and Priority: Newton versus Leibniz Clarendon Press, Oxford 1993, pp.22-

23

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Sarpi prefers 3 (perception followed by reason) because it starts with what is real and then

allows the derivation of meaning from it. We must ask what Sarpi meant by “reason” in 3;

was it the same as Newton’s prescription of induction from experimental observation or

testimony of the senses?

We also need to ask why Sarpi was choosing between these four options. If he was aware of

Galileo’s ongoing correspondence with Kepler, then he would certainly have had been

interested to look into the work of the energetic and capable Johannes Kepler. Kepler’s

Mysterium Cosmographicum was first published in 1596 while Paolo Sarpi became state

theologian to Venice 10 years later. Given Kepler’s tactful questioning of the church’s

orthodoxy on the movement of the sun, and Sarpi’s own atheism (curious for a theologian),

Sarpi must have been able to understand that the Neoplatonic school itself had no respect for

church dogma even with its mindset of a divine Creator which Sarpi found necessary to reject.

Sarpi wrote of his fears for Galileo in being called to Rome by certain cardinals to explain his

support for the Copernican theory.290 At the same time, Venice was seeking to neutralise the

influence of the Catholic Church.291 (Wootton refers to Sarpi as a “Protestant conspirator”.292)

Thus, Sarpi saw the opportunity to stoke conflict between forces that arose from rationality

(represented in part by the cultural tide that Kepler merely typified) – which he opposed – and

the worldly authority and wealth of the Roman Catholic Church which also represented the

Hellenic cultural current albeit largely corrupted by ambitious or weak-minded sections of its

officers (i.e. clergy, etc).

We are seeing that cultural currents were at play independent of the influence of any particular

figure, but which could be influenced or capitalised upon by shrewd, committed or capable

persons. Kepler, Sarpi and Leibniz are examples of such persons; chronologically, Sarpi sat

between the other two. Sarpi was a contemporary of, though elder to, Kepler while Leibniz

was born after Sarpi had passed on. Sarpi lived amidst the conditions which gave rise to the

Thirty Years War, while Leibniz’s educators (particularly Jakob Thomasius), wider network

and Leibniz himself dealt with that war’s aftermath both politically and philosophically.

Sarpi’s influence in England

Sarpi corresponded with Francis Bacon who acted as an inspiration for the founders of the

English Royal Society. Indeed, “[l]etters are still extant showing his [Sarpi’s] friendship with

Lord Bacon”.293 Perhaps some of the lost letters would shed light on the origins of the Royal

Society, an organisation of political as well as scientific importance to this day. The

connection is worth looking into because the Venetian Party was an established force in

English politics at the time, and was instrumental in what became the British East India

290 “Per mia memoriae” (“From my memory”) Schedae Sarpianae (Writings/Manuscripts of Sarpi) in Robertson,

A. Fra Paolo Sarpi: The Greatest of the Venetians George Allen & Company, London 1911, pp.73-75 291 Sarpi himself was excommunicated in 1607 by the Inquisition. Robertson, A. Fra Paolo Sarpi: The Greatest

of the Venetians George Allen & Company, London 1911, p.152 292 Wootton, p.46 quoting from Sarpi’s Pensiero no.146 293 Robertson, A. Fra Paolo Sarpi: The Greatest of the Venetians George Allen & Company, London 1911 p. 84

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Company. Paolo Sarpi was the most frequently translated Italian writer in 17th Century

England,294 which indicates quite an influence given that the English looked to Italians for

intellectual leadership in that period.

Given Sarpi’s relationship to Galileo and indirect relationship to Kepler and his stance on how

science should proceed, it would be consistent that he should try to influence the course of

science. It might not be coincidental that the Baconian approach to science which came to

dominate the Royal Society is so closely allied to Sarpi’s empiricist outlook.

Leibniz was picking up the pieces of Kepler’s approach to science and carried that standard,

even while Empiricism rose in prominence particularly in the circles of the Royal Society

perhaps in the wake of the influence of Sarpi.

Sarpi’s closeness to Galileo

We talk about Sarpi because scientific and political battles often go together. Venice was a

political and financial centre of Europe during the 15th through 17th Centuries. Sarpi was

Galileo’s patron and was said to be the first to look through Galileo’s telescope. Robertson

says that Galileo and Sarpi actually constructed the telescope together, and that that telescope

was then presented to the Doge of Venice, Leonardo Donato, as a gift.295 Indeed, Sarpi was, at

least initially, a mentor to Galileo in astronomy “as he [Sarpi] had had the start ... of his friend

[Galileo] in the study of astronomy and its cognate sciences, the advantage lay with him

[Sarpi]”. However, “Galileo, instead of being jealous of Fra Paolo, was jealous only for his

honour and pre-eminence, calling him ‘Il mio pare e maestro’ – ‘My father and my

master.’”296

Sarpi is said to have gathered a group of young noblemen around him and secretly

communicated with them his conception of Atheism. Further, patrons are rarely dispassionate

about or detached from the work they finance, including Venetian patrons. The fact that Sarpi

was chief theological advisor to the Venetian republic while maintaining a secret Atheism

makes him particularly curious. Wootton argues that Sarpi did try “to give practical

implementation to ideas he had expressed in private: his political activities were intended to

subvert religious authority in general, his published works were intended to undermine the

foundations of religious argument.”297

We must ask whether Sarpi was privy to any of the correspondence between Kepler and

Galileo. We suggest only a communication of methods and mindset. Given the fundamental

differences between Kepler’s outlook on science and God, and Sarpi’s, and the Venetian

294 Tedeschi, J. (review) “Venetian Phoenix: Paolo Sarpi and Some of His English Friends (1606-1700) by John

L. Lievsay” Modern Philology Vol. 75, No. 2 (Nov., 1977), pp. 191-194 295 Robertson, A. Fra Paolo Sarpi: The Greatest of the Venetians George Allen & Company, London 1911 pp.

73-74 296 Ibid., p.73 297 Wootton, D. Paolo Sarpi: Between Renaissance and Enlightenment Cambridge University Press, 2002, p.46

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Republic’s reputation for intrigue,298 the closeness of Sarpi to Galileo and the friendship

between Galileo and Kepler warrants more research.

Sarpi and atheism

Pietro Pompanazzi is an important intellectual figure of the 16th Century. For our purposes

here, Pompanazzi’s is relevant to one particular issue. In The Treatise on the Immortality of

the Soul (1516) Pompanazzi argued that, to a degree, the soul is inseparable from the body

and to that extent the soul is mortal.299 This was at odds with Thomas Aquinas’ reading of

Aristotle as consistent with Christian theology.

Wootton explains that Sarpi’s Pensiero no. 4 reproduces Pompanazzi’s argument to

demonstrate the mortality of the soul.300,301 Averroes argues that humans participate in an

immortal reason and so the rational was essentially, or behaved as if it was, immortal although

it is actually mortal. Pompanazzi said that man is a mean between mortal and immaterial

things. However, his essay Immortalitate Animae refutes every argument it puts in favour of

the immortality of the soul302 and ends with an almost patronising sop to the Platonic and

Christian belief in the immortality of the soul.303

Wootton says that Sarpi’s Pensieri adopted Pompanazzi’s arguments against the immortality

of the soul, and then makes the case that Sarpi was relatively isolated in holding his views as

outlined in the Pensieri.304 Wootton misunderstands the meaning and role of “political views”.

It is not necessary for many/any to adopt those views overtly for them to be used and even

provide a steering role for the Council, particularly if Sarpi was important in Venetian

political circles and especially if the views expressed were of value to Venice.

Some of Sarpi’s contemporaries were awake to what he was doing and were unafraid to speak

out. For example, Tommaso Campanella was an anti-Venetian polemicist who argued that the

inevitable outcome Venetian policy was a society of moral atheists. Wootton explains that

Campanella’s warning against Sarpi’s methods provides a direct link between Sarpi’s Pensieri

and the principles adopted in/by the Venetian policy during the Interdict.305

298 For example, see any English edition of The Ghost Seer by Friedrich Schiller and The Bravo by James

Fenimore Cooper. Also refer to Othello: Moor of Venice by William Shakespeare wherein Venetian methods

are represented by Iago. 299 Perfetti, S. “Pietro Pomponazzi” 2004 in Stanford Encyclopedia of Philosophy. Accessed at

http://plato.stanford.edu/entries/pomponazzi/ on 28 April 2012 300 Wootton, p.41 301 See de Immortalitate Animae by Pompanazzi, chapter 4 302 Pompanazzi, P. Immortalitate Animae “On the immortality of the soul” in Cassirer, E., Kristeller, P. O.,

Randall, J. H. Jr (eds and trans.) The Renaissance Philosophy of Man Phoenix Books, University of Chicago

Press 1948, pp.280-380 303 Ibid., pp.380-381 304 Wootton, p.47 305 Ibid., p.46

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Sarpi and Newton

Whatever Sarpi’s influence on Galileo may have been, we certainly find much of Sarpi in

Newton. Reading the account of Galileo’s conception of simplicity in nature following the

account of Kepler, we begin to see that the core of Newton’s scientific method was not new.

However, its Averroism and its Atheism were new. We say Averroism because Newton

required that each conclusion be based strictly on observations without leaps of faith or leaps

of understanding even if the intention is to test that leap by experiment. No conclusion is

allowed unless it strictly and evidently follows from what is observed. This is a kind of

Averroist rigor, and it was a long way from Galileo’s scientific method. Burtt explains that

Galileo said that logic is no tool for discovery and, indeed, Galileo is not a priori to the

degree that Kepler was.306 Burtt explains that Galileo is close to Kepler in scientific

mindset.307 However, there may have been differences in their conceptions of God.

David Wootton explains that Sarpi espoused an empiricism similar to Newton’s: the best way

of philosophising, Sarpi says, is to begin with the evidence/testimony of the senses and to use

reason to build upon that. Wootton does not explain what kind of reason (clinically inductive

or otherwise) Sarpi advocates. Sarpi explicitly rejects perception following reason because a

priori reason can only be speculation.308 All of this, of course, is similar to Newton’s position.

From Galileo to Newton

Burtt presents Galileo’s understanding that sensory perception, including experimental

observation, often delivers misleading results.309 Application of reason guided Aristarchus and

Copernicus to conclusions contrary to observations. To say that it was purely “simplicity” that

guided their reason would be to ignore their wider and richer intellectual and cultural

environment. In any case, what is missing from the simplicity doctrine is the higher

hypothesis which, to be sure, is often more beautiful and harmonious than the view “in the

small” that had been being taken. That shift in thinking may not at first sight appear to be

simple. Perhaps a circle is simpler than a polygon, but not when one has been reared on

polygons and is trying to regard a circle as an infinite-sided polygon.

In any case, it appears that Newton lifted the “simplicity” idea from Neoplatonists such as

Copernicus, and added it as a qualification to a purist Empiricism.

Galileo follows these steps:

1. Intuition or resolution (hypothesis)

2. Demonstration

306 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, p.65 307 Ibid., pp.65-8 308 Wootton, p.37 309 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, pp.68-9

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3. Experiment.

The Royal Society’s “British” approach to science involves repeating experiments, finding a

pattern, expressing the pattern mathematically and calling that a law. This might be called a

“statistical” approach. It has the benefit of discouraging thinking that is inexact or too

speculative.

The more usual approach, closer to Galileo’s three step and taught in Australian high schools

in the 1980s, is to form a hypothesis, design an experiment to test the hypothesis, and conduct

the experiment. Alternatively, one could check data from experiment or observation against

the hypothesis. Australian high school curricula omit the question of how hypotheses are

formed. Kepler’s a priori understanding of how God thinks and acts would be relevant and

useful in filling that gap.

Leibniz comments on the experimental program of the (British) Royal Society

In New Essays on Human Understanding, Leibniz called the causes of phenomena “true

hypotheses”, and says that if the art of discovering true hypotheses is not joined to Bacon and

Boyle’s art of experimenting, “we shall never with utmost cost attain [from experimenting] …

what a man of great penetration might discover at first sight.” Leibniz notes that Descartes

made a similar remark regarding “the method of the Chancellor of England [i.e. Sir Francis

Bacon].” He then notes Spinoza’s observation to the Secretary of the Royal Society,

Oldenburg, that Sir Robert Boyle “stops a little too long to draw from a great number of fine

experiments no other conclusion than this which he might take for a principle, namely, that

everything takes place in nature mechanically; a principle which can be rendered certain by

reason alone, and never by experiments however numerous they may be”.310

Newton’s prescribed method of discovery

Contrast this Newton, from an article by McGuire:311

1. The Method of Analysis should always precede the Method of Composition when

investigating difficult problems in Nature and in Mathematics.

2. This “Analysis” is making observations and drawing general conclusions from them

by induction.

3. Hypotheses are not to be regarded in experimental philosophy.

4. Admittedly, arguing from experiments and observations by induction does not

demonstrate general conclusions, yet it is the best method available as admitted by the

Nature of Things. Further, the argument may be regarded as stronger by the level of

generality of the Induction. I.e. a more general Induction is a stronger argument.

310 Leibniz, G.W. New Essays on Human Understanding Book IV Chapter 12 §13 in Wiener, p.479-480 311 McGuire, J.E. “Newton’s ‘Principles of Philosophy’: An intended preface for the 1704 Opticks and a related

draft fragment” The British Journal for the History of Science 1970 vol. 5 no. 2 pp. 178-186, at pp.184-5

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5. If no exception/contradiction arises in phenomena, then the conclusion may be

accepted generally.

6. If at any future time an exception is found in experiments, then the conclusions are to

be pronounced with the exceptions.

7. Thus, we proceed:

From Compounds to Ingredients,

From Motions to the Forces producing them in general, from Effects to Causes

and from particular causes to more general ones,

…until the argument ends in the most general causes.

This is the method of Analysis. The Synthesis comprises (i) assuming the causes discovered

and established as principles, and (ii) using the causes to explain the phenomena proceeding

from the causes. Further, the causes/principles are used to prove the explanations.

This is the method that Copernicus used, as Kepler explains.312 Newton’s summary starting

“This is the method of Analysis” is a restatement of Kepler’s claim that Copernicus’

conclusions could be proved with Euclidean exactitude, and a priori too. At that same page,

Kepler is clearly working entirely within the domain of hypotheses. He first refers to the

“customary hypotheses” with an excessive number of circles, and then to Copernicus’

hypothesis with far fewer circles.

In point 7 above, in light of point 4, when Newton refers to “causes”, it appears that he is

referring to correlations. If Motion B always follows Force A, then A causes B. What if there

is an undetected phenomenon that is causing both A and B? Newton’s concept of Cause

requires more examination.

In point 3 above, Newton says Hypotheses are not to be regarded in experimental philosophy,

i.e. we must always argue by induction from the observational data. But does Newton posit a

method other than experimental philosophy in which Hypotheses are permitted?

In the next section, a thesis on the origin of Newton’s method of discovery that was first

presented by Mamiani in 2001 is described. It is argued that Newton’s source was a logic text

by Robert Sanderson published in 1618 which is essentially a Ramist logic text, meaning in

the tradition of Petrus Ramus who lived in Europe from 1515 to 1572. Ramus’ influence was

largely through his logic texts rather than on logic itself. While Ramus energetically promoted

the need for reform in the Aristotelian curriculum of the time, it was not so much that he

thought that the content of the curriculum was incorrect as the way in which it was taught. For

example, he thought that students were required to spend too many years learning material

which ultimately would not be useful to them. Also, Ramus argued, the many years required

for study meant that education was too expensive for children from poor families.313 An

extended discussion of Ramus is beyond the scope of this thesis.

312 Duncan, A.M. trans. Kepler, J. Mysterium Cosmographicum Abaris Books, Janus Series Norwalk USA 1981,

pp.77-79 313 Selberg, E. “Petrus Ramus” 2006 revised 2011, in Stanford Encyclopedia of Philosophy Zalta, E.N. (ed.).

Accessed at http://plato.stanford.edu/entries/ramus/ 11 Aug 2012

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Evolution of Newton’s method of discovery

Mamiani in Isaac Newton’s Natural Philosophy (“INNP”) describes the origin of Newton’s

regulae philosophandi as this transformation:314

1. Robert Sanderson’s Logicae artis

compendium (Oxoniae 1618)

which Newton read c.1661-4 and which

follows the Ramists rather than the

Scholastics, in that it emphasizes the theory

of method

2. Newton’s Treatise on the apocalypse 16 rules

3. Newton’s Principia 1st ed. 1687 2 rules

4. Newton’s Principia 2nd ed. 1713 3 rules

Noteworthy points regarding the Treatise on the Apocalypse are:

1. The rules are ordered from most to least general, as Sanderson ordered his rules.

2. Their literary style is similar to that in Descartes’ Discours de la méthode.

3. The 12th rule is from Descartes’ Discours: “Every truth I found is the rule that I need

afterwards to find other truths”.

Mamiani is intentionally seeking a transformation process of these rules of philosophy,

emphasizing the inductive nature of the process.

The original of Sanderson gives the method of invention as having no law, unlike methods of

resolution and composition which are stated as having five laws in common. Rather, the

method of invention is given as having means-cum-steps:

1. Sense

2. Observation or history (which includes “data”)

3. Experience

4. Induction.

Sanderson says that the method of invention has nothing in common with the method of

resolution or analysis.

True to the statement of Analysis by Newton, Newton writes to Oldenburg with a plan to

simplify the rules of optics to the most general form.

314 Mamiani, M. “To twist the meaning: Newton’s regulae philosophandi revisited” in Buchwal, J. and Cohen I.

eds. Isaac Newton’s Natural Philosophy MIT Press, Cambridge MA 2001

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Newton lists laws which, says Mamiani, start with these from Sanderson’s Logicae artis

compendium or Compendium of the Art of Logic:

The law of brevity

The law of harmony

which are then transformed by Newton to:

(a) Observe the consent of the Scriptures

(b) Choose constructions which reduce contemporary visions to the greatest harmony of

their parts.

Newton against hypothesis and towards mathematicization

Newton’s stance against Hypothesis is affirmed and elaborated by Burtt.315 Koyré writes, “one

can interpret the Newtonian view [of hypotheses] as the end-product of the English tradition

of empiricism, that of Bacon and of Boyle”.316 Newton’s four laws of scientific enquiry are

then given:317

1. We are to admit no more causes of natural things than such as are both true and

sufficient to explain their appearances.

2. To the same natural effects we must, as far as possible, assign the same causes.

3. The qualities of bodies, which admit neither intension nor remission of degrees, and

which are found to belong to all bodies within the reach of our experiments, are to be

esteemed the universal qualities of all bodies whatsoever.

4. In experimental philosophy we are to look upon propositions collected by general

induction from phenomena as accurately or very nearly true, notwithstanding any

contrary hypotheses that may be imagined, till such time as other phenomena occur,

by which they may either be made more accurate, or liable to exceptions. This rule we

must follow, that the argument of induction may not be evaded by hypotheses.

Knowledge without sensation

The fourth of these affirms that empirico-deductive interpretation to be given to the first three.

Newton goes beyond Galileo and Sarpi’s empiricism by asserting that it is not only

methodological limits that prohibit hypotheses but also the nature of what is knowable.

Indeed, the upshot of the fourth law is that nothing is known or can be known beyond

experimental results (p.216). The exclusion of hypotheses acts as a prohibition on creative

mentation. This repeats one of Pompanazzi’s arguments against the immortality of the soul:

that “the intellect is inseparable from matter”318 which might imply – as Wootton says – that 315 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, pp.211-213 316 Koyré, A. Newtonian Studies Chapman & Hall, London 1965 p.40 317 Ibid., pp.214-216 318 Pompanazzi, P. Immortalitate Animae “On the immortality of the soul” in Cassirer, E., Kristeller, P. O.,

Randall, J. H. Jr (eds and trans.) The Renaissance Philosophy of Man Phoenix Books, University of Chicago

Press 1948, p.293

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“there is no knowledge without sensations”.319 Sarpi adopted the position that “there is no

knowledge without sensations” in his Pensiero No. 4.320 Nor did this idea stop at Sarpi. John

Locke adopted it saying, “The knowledge of the existence of any other thing we can have

only by sensation: for there being no necessary connexion of real existence with any idea a

man has in his memory.” Further, “the having the idea of anything in our mind, no more

proves the existence of that thing, than the picture of a man evidences his being in the

world.”321 (emphasis in original) Leibniz argues the contrary in New Essays giving the

example that we are certain that Julius Caesar lived without having had direct sensation of the

phenomenon. Leibniz refers to knowledge arising from “immediate internal experience of an

immediateness of feeling” as “primitive truths of fact”.322 We add that Leibniz – knowingly or

otherwise – was reiterating Hermes Trismegistus.323 In Bruno’s De umbris idearum published

in Paris in 1582, the character of Hermes introduces a philosophy in which “The intellect

stands certain of what it instructs whereas the senses are falsely moved”.324

For Newton, mathematics had a role in describing observed phenomena precisely. Using the

mathematical description, one then simplifies that description as far as possible.325 From

Newton’s laws of scientific enquiry, one’s observations in mathematical expressions are

reduced to something like a simplest “normal form”. Thus, mathematical symbols are

descriptive of observations, and do not represent Platonic ideas or anything incorporeal.

Newton said that reducing motion to his three laws of motion was an achievement, but if a

single cause of all three can be “found out” so that they can be reduced to a single equation

then that will be an even greater achievement. It must be asked how a “cause” can ever be

found when all one has is descriptions of observations.326 Only correlations are observable,

not causes. Newton says that deductions from observations are allowed, so that better

experiments can be designed. Yet one wonders how experiments could have been designed in

Kepler’s time that would have allowed Kepler to “deduce” the inverse square law of gravity.

Koyré argues that Newton’s hostile attitude to hypotheses can be detected throughout

Newton’s career and, indeed, “the antihypothetical attitude is present – though in a much less

rigid form – in the very first works of Newton.”327

319 Wootton, p.41 320 Ibid. 321 Locke, J. Essays on Human Understanding Vol. 2 Book IV Chapter XI, Project Gutenberg edition accessed at

www.gutenberg.org 322 Leibniz, G.W. New Essays on Human Understanding Vol. 2 Book IV Chapter II §1, Bennett, J. (trans.) 1st ed.

Feb 2005, amended April 2008, p.166 Accessed at www.earlymoderntexts.com/jfb/leibne.pdf 10 May 2011 323 To Hermes Trismegistus, there is for humans a symbiosis between understanding and sensation, but

understanding and sensation are distinct because understanding comes to be especially by the agency of the

mind. Corpus Hermeticum IX §2 in Copenhaver, B.P. Hermetica Cambridge University Press 1992, p.27 324 “Hunc intellectus non errans stare docet: Sensus autem fallax suadet moueri.” Giordano Bruno De Umbris

Idearum Paris 1582 digital edition Peterson, J.H. (trans.) 1997 accessed at

http://www.esotericarchives.com/bruno/umbris.htm 27 April 2012. 325 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, pp.216-8 326 Ibid., p.219 327 Koyré, A. Newtonian Studies Chapman & Hall, London 1965, p.40

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Kepler and Leibniz in Newton’s method

Mamiani says that in the 9th rule of Newton’s Treatise on the Apocalypse, Newton makes clear

that simplicity is a consequence of the law of harmony, and then quotes from the 9th rule:328

To choose those constructions which without straining reduce things to the greatest

simplicity. ... Truth is ever to be found in simplicity, and not in the multiplicity and

confusion of things. As the world, which to the naked eye exhibits the greatest variety

of objects, appears very simple in its internal constitution when surveyed by a

philosophic understanding, and so much the simpler by how much the better it is

understood...

Kepler’s dedicatory epistle to Mysterium Cosmographicum emphasizes the beauty, brilliance

and harmony of creation more than its simplicity. Later in Mysterium Cosmographicum when

considering hypotheses, Kepler explicitly prefers the simple to the convoluted. Leibniz in

1686 reiterated Kepler, “Reason wishes to avoid multiplicity in hypotheses or principles very

much as the simplest system is always preferred in Astronomy.”329,330

Newton seeks simplicity by combining, transforming, resolving rules generated by

observations. Importantly, we see that Newton adopts a mechanical process of discursive

logic to “derive” the laws of nature from observations. For Leibniz, this was nothing but the

“art of reasoning well”, quite distinct from the “art of discovery”.331 In 1677, Leibniz

elucidated on his boyhood ambition of creating a Characteristic whereby reasoning could be

conducted in a symbolic language comprehensible to people of all classes and nations so that

disputes could readily be settled.332 The important thing is that what for Newton was

appropriate for discovery, for Leibniz was extremely useful for reasoning and teasing out the

implications of existing knowledge.

As far as discovery is concerned, Kepler had gone the opposite way to Newton by forming a

hypothesis that is harmonious and beautiful, and then going about calculating the connection

between it and the observations.

Regarding Newton’s approach in Treatise on the Apocalypse, which was written prior to

Newton’s Principia, Mamiani writes:333

328 From Yahuda Manuscript 1.1a in Mamiani, M. “To twist the meaning: Newton’s regulae philosophandi

revisited” in Buchwal, J. and Cohen I. eds. Isaac Newton’s Natural Philosophy MIT Press, Cambridge MA

2001, p.6 329 Wiener, p.296 330 It may be stretch to draw a connection. However, the seeking after simplicity goes back to Hermes

Trismegistus. He writes, “The many make philosophy obscure in the multiplicity of their reasoning.” He says

that they (the many) combine philosophy with arithmetic, music and geometry, so making it

incomprehensible. Instead, “Pure philosophy that depends only on reverence for god should attend to these

other matters [arithmetic, music and geometry]” leaving only problems in astronomy unsolved. “Asclepius”

§§12-13 in Copenhaver, B.P. Hermetica Cambridge University Press 1992, p.74 331 c.1693, Wiener, pp.77-78 332 1677, Wiener, p.18 333 Mamiani, M. “To twist the meaning: Newton’s regulae philosophandi revisited” in Buchwal, J. and Cohen I.

eds. Isaac Newton’s Natural Philosophy MIT Press, Cambridge MA 2001, p.7, middle paragraph

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What is new in Newton’s rules? Neither the content nor the expression. It is true that

Sanderson’s laws are very concise whereas Newton’s rules are verbose and redundant.

We must wait for the rules of the Principia in order to find a conciseness equivalent to

the laws of Sanderson’s Logic. There is, however, a great difference among Newton’s

rules of interpreting the Apocalypse and Sanderson’s laws. Sanderson is repeating the

precepts of a dead tradition for presenting or teaching acquired knowledge. Newton

[on the other hand] is proposing rules to be used in discovering new knowledge.

This suggests the source of the current view of:334

the English “Baconian” concept of how to do science, followed by the Royal Society.

You’re supposed to collect lots of observations and reports, do experiments, then

generalise to laws, then (optional) think up causal hypotheses (e.g. atomism) that

might explain them. That’s an OK method to do science, especially if the science you

want to do is very empirical, e.g. chemistry. And very British and practical.

Leibniz was not “anti”-discursive logic or propositional logic. Indeed, Leibniz has been called

the most original logician of the 17th century and credited with many original discoveries

including the beginnings of what is now regarded as standard classical propositional logic

decades if not centuries before others.335 The difference is that Leibniz would only have

regarded this as a way of interpreting existing knowledge, or to answer questions which could

be answered from the existing body of human knowledge. This is no small thing, and Leibniz

aimed with his universal/general characteristic even to allow disputes between people and

perhaps nations to be resolved. This coming from Leibniz the diplomat was quite an

ambition.336 However, it is different from making a new discovery. We will see in a later

chapter that when Leibniz considers the principles and process of new discovery or “the art of

discovery”, a different field of considerations comes into play.

Consequences of mandating empirico-logic

What if experiments cannot be designed but only hypothesising is possible? An example is the

quest to understand the solar system using observational data collected from earth. It can

surely be demonstrated that restricting ourselves to Sanderson’s induction/deduction

precludes leaps of understanding, inspiration and anything that smacks of human creativity

under most definitions. No a priori presumption of harmony is permitted. Newton has

certainly excluded Cusa’s “learned ignorance” in which leaps of knowledge arise from

inspiration rather than from “discursive logic”. Science and mathematics would cease. For

example, consider the famous case of Gauss answering his teacher in adding the integers from

1 to 99. No doubt there would have been an admixture of some kind of deduction alongside

an “aha!” sense of inspiration. We are now as much in the domain of psychology as science.

Leibniz, in his essay “How to Reason Well”, named the holding of all aspects of a body of 334 Private communication from Prof. Jim Franklin, UNSW, 23 Aug 2009 335 Cambridge History of 17th Century Philosophy C.U.P. 1987, pp.141-3 336 Loemker 1969 p.224 and Wiener 1951, pp.23-24. Loemker ascribes this writing to c.1679 and calls it “On the

general characteristic”; Wiener dates it 1677 and calls it “Towards a Universal Characteristic”. This writer

thinks both translations/interpretations are fair.

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knowledge in one’s mind at once as a prerequisite to full understanding and formulating a

hypothesis as to the solution to a problem.

There are serious consequences of Newton’s mandate for science:

1. Painfully slow progress in scientific thought and understanding which suggests that

Newton himself – perhaps without being conscious of it – did not follow his precepts

in his own scientific work;337

2. Acceptance that causes are not known unless observed, and may not be speculated

upon;338

3. Resignation to the unknowability of nearly everything; and

4. Prohibition of ideas, which would have prevented Leibniz’s calculus, complex

numbers and much of Plato’s own reasoning.

Leibniz actually noted that an overemphasis on amassing experimental data and an

underemphasis on reasoning was retarding scientific progress at the Royal Society. Some

years after his 1673 visit to the Royal Society in London, Leibniz wrote, “they confessed to

me in England that the great number of experiments they have amassed gives them no less

difficulty than the lack of experiment gave the ancients”.339 At the same time, Leibniz tried to

reconcile the pragmatic need for experiment with a priori reasoning.340

Burtt sums up Newton’s approach in, “Science is the exact mathematical formulation of the

processes of the natural world. Speculation is at a discount, but motion has unconditionally

surrendered to the conquering mind of man.”341 (emphasis in original) Actually, the

Newtonian method says that science is the exact mathematical description of the observable

processes of the natural world, and this stems from Newton’s failure to embrace the method of

337 Ihmig is similarly sceptical. He writes, “The strict rejection of hypotheses in experimental philosophy,

however, hardly seemed to agree with how Newton practiced science. As hypotheses can be found in all

editions of the Principia, some authors have tried to determine the meaning of the concept of hypotheses and

its various forms more precisely. This has made it possible to separate ‘good’ from ‘bad’ hypotheses, thus

confining Newton’s rejection of hypotheses merely to the bad ones.” Ihmig, K.-N. “Newton's Program of

Mathematicizing Nature” in Hoffmann, M.H.G., Lenhard, J., Seeger, F. (eds) Activity and sign: grounding

mathematics education Springer 2005, p.242 338 In New Theory about Light and Colours 1672, Newton had already rejected the use of hypotheses. In the

Principia 2nd ed. 1713, Newton admits the difficulties that avoiding hypotheses is causing him, but reiterates

the validity of avoiding hypotheses: “But hitherto I have not been able to discover the cause of those

properties of gravity from phenomena, and I frame no hypotheses; for whatever is not deduced from the

phenomena is to be called an hypothesis; and hypotheses, whether metaphysical or physical, whether of

occult qualities or mechanical, have no place in experimental philosophy.” 339 Letter to Herzog Friedrichm, 1679 in Wiener, p.xxiii. Wiener also writes, “It is in his correspondence

concerning the experimentalists of the Royal Society of England (whom he had visited in 1673) that Leibniz

reveals most clearly what he thought his logical instrument could do, and what the plain empiricists were not

doing, namely, to elicit all the knowledge deducible from a given number of presuppositions. Lack of a

proper art of demonstration had made it necessary, in Leibniz’s opinion, for Baconian experimental

philosophers like Boyle to resort to many observations in order to find out what Galileo and Descartes were

able to know by reasoning.” Wiener, p.xxii. Wiener does not say whether the “logical instrument” is the

Universal Characteristic. 340 Letter to Berthey, 1677, in Wiener, pp.xxiii-xxiv 341 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, p.223

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hypothesis even if Newton did not outright reject the use of hypotheses. Further, motion has

not unconditionally surrendered to the mind but, rather, the mind of man is surrendering to the

bodily senses’ observation of motion, which enslaves the mind by denying its capability to

reason or create.

Burtt rebuts the contention that Newton is free of metaphysical concerns or crutches. In fact,

the “objective rigor” of Newtonian science is replete with metaphysical assumptions which

we outline below. Newtonian positivism is the idea that truth can be acquired without

presupposing any theory of their ultimate nature, such as of the Creator. Burtt says that

anyone who claims to be free of metaphysical assumptions actually does adopt metaphysical

notions in these ways:342

1. “He will share the ideas of his age on ultimate questions, so far as such ideas do not

run counter to his interests or awaken his criticism”;

2. “If he be a man engaged in an important enquiry, he must have a method, and he will

be under a strong and constant temptation to make a metaphysics out of this method”;

3. “Since human nature demands metaphysics for its full intellectual satisfaction, no

great mind can wholly avoid playing with ultimate questions, especially where they

are powerfully thrust upon it by considerations arising from its positivistic

investigations, or by certain vigorous extra-scientific interests, such as religion.”

The way Newton said science should be done and the way that Newton actually did science

were two different things. Newton himself did not proceed by pure induction in his own work.

Burtt goes on to explain how and in what way Newton adopts metaphysical assumptions of all

of the above three kinds. Koyré disputes that Newton followed his own prescription on

hypotheses. Koyré writes, “The expression ‘hypothesis thus seems to have become, for

Newton, toward the end of his life, one of those curious terms, such as ‘heresy,’ that we never

apply to ourselves, but only to others. As for us, we do not feign hypotheses, we are not

heretics. It is they, the Baconians, the Cartesians, Leibniz, Hooke, Cheyne, and others – they

feign hypotheses and they are the heretics.”343

We now make some comments on logical deduction which will usher in the next chapter.

Empirico-logic in other domains

Empirico-logic was promoted under a different guise by the contention that a computer

equipped with sensory apparatus and programmed with the rules of logic can replicate the

human mind. Thus von Neumann’s viewpoint is at its heart the same as the rules of

Newtonian science. This dissertation will not investigate this question further.344 Despite the

342 Burtt, E.A. The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed.

reprinted 1950, p.226 343 Koyré, A. Newtonian Studies Chapman & Hall, London 1965, p.52 344 This author’s MPhil thesis “On object Petri nets” (University of Warwick, Department of Computer Science,

2004) dealt with Petri nets which seek to model complex systems using enhanced graph-like models which

carry tokens under deterministic rules, like a pinball machine in which the balls run through tubes. Nested

Petri nets use nets themselves as tokens and so can represent greater complexity. Some nets can be reduced to

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fact that he was a designer of machines and even of a calculating machine, Leibniz could not

have shared von Neumann’s view. For a start, the human soul is a monad which is connected

with every other monad in the universe and has full knowledge of everything that is occurring

in the universe, which is quite unlike any computer. If Leibniz regarded the action of the mind

of man as God in the miniature,345 then there is another raft of reasons why Leibniz would

disagree, since few would argue that God can be modelled by a computer.

Euclidean geometry presents a system of formal reasoning, essentially embodying the idea of

the syllogism. Plato embraces such reasoning with a geometrical problem in Meno. Plato also

demonstrated how reasoning can be conducted on non-mathematical ideas, such as justice and

goodness. There was a raft of mathematical thinkers in Ancient Greece who were able to

reason both in the abstract and in the concrete. Their work raises the question of the

relationship between abstract formal reasoning and the real world. It also raises the question

of the relationship between abstract ideas and the physical world.

Reasoning other than empirico-logical

We become aware that there is a mode of thought that is not formal reasoning, as such, but

which is structured and is worthy of the name reasoning. Indeed, Archimedes performed work

in his own way, but when he recorded or transmitted what he had found, he used formal

reasoning of a kind which was not what he used to reach the discovery in the first place. At

the same time, the actual method he used was not to simply “throw things together and watch

what happened” either. There was a searching for an order that was indefinable because it had

not yet been found. He would recognise it when he found it, though he might be misled many

times along the way. The search for order or harmony was undertaken with a sense of

necessity or passion and that search amounts to the search for a viable hypothesis. Leibniz

wrote, “The art of discovering the causes of phenomena, or true hypotheses, is like the art of

deciphering, where an ingenious conjecture often shortens the road very much.”346 The formal

reasoning was often not part of the search and was only added afterwards. Of course,

confirmation by formal reasoning or by experiment must follow.

Boyer notes that Archimedes of Syracuse “tempered the strong transcendental imagination of

Plato with the meticulously correct procedure of Euclid.”347 Boyer suggests how Archimedes

did this in one case: that Archimedes used infinitesimal considerations as an heuristic method

“simply as an investigation preliminary to the rigorous demonstration by the method of

exhaustion.”348 It could be argued that the heuristic method represents the transcendental

a linear logic proposition. Net-based models are essential for systems such as telecom networks, computer

chips and circuit boards. Attempts to use nets to model processes with a human element have seen a

resurgence with the modelling of social networks such as those found on Facebook or LinkedIn. As yet, there

is no convincing argument that net-based models bear any qualitative resemblance to the mind or to thought

processes. 345 Leibniz, G.W. Theodicy §147 346 Leibniz, G.W. New Essays on Human Understanding Book IV Chapter II §13 in Wiener, p.479 347 Boyer, C. The History of the Calculus and its Conceptual Development Dover Publications, New York 1949,

p.48 348 Ibid., p.51

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imagination of Plato while the method of exhaustion represents Euclidean rigor. However,

must there be an exclusive choice between transcendental imagination and rigor?

Platonists were never opposed to rigor, and not even opposed to the kind of work that Euclid,

for example, did. The difference was that the Platonists insisted that there was an indefinable

something that was the quarry of any process of discovery or creativity, and it is always in

that that the crux of any question in science or philosophy lies. The Pythagoreans insisted that

such concepts were valid, and number was the key example in their time. Such concepts

should be the focus of science but, in doing so, the human mind becomes the centre of

science. We conclude that the human mind must be intertwined with what science is. This is

not as Burtt understood things in opposing the Russellian pessimism and the Newtonian

empiricism. Burtt argued that human experience was intertwined with science. On the

contrary, we would argue that the Leibnizian view is that the pure ideations of the human

mind are where science actually takes place. These are tested in the world, as Archimedes did

in his bath tub or as Huygens and Papin did with their work towards building powered

engines. Adopting Leibniz’s view would resurrect what Burtt instinctively knew to be right

but could not quite understand – that Dante’s conception of Man as the jewel of Creation due

to the uniqueness of Man’s mind was correct and the Newtonian-cum-Russellian notion is

unsustainable. The Russellian notion is that Man is not only insignificant in Creation but is

not even part of Creation, except for Man’s biological body. The inexorable conclusion from

the Russellian notion is that the mind has no role in science.

Burtt purports to bring humanity back into the universe by saying that human experience is a

scientifically “good enough” representation of the physical universe. This is essentially

Cartesian subjectivism. As Plato said in The Republic, all experience is opinion, which flies in

the face of Burtt’s resolution. We prefer to solve the paradox that Burtt correctly posed using

Leibniz’s essays. Leibniz’s metaphor is that reason is akin to life while experience is the air

essential to “life” in that it gives context and subject matter to reason about. An alternative

analogy is that the mind is the potter and the experience is the clay which gives subject matter

to the mind.

The role of rigorists

Where did mathematics of the kind we now know originate? For a history of mathematics in

toto, we can refer to Ball, Boyer and many others. Suffice it to say that the Pythagoreans and

Neoplatonists and their descendants made strides in mathematics, and it was generally the role

of the rigorists, as Leibniz called them, to complain that a certain innovation could not be

done or was not allowed. Such critics still played the role of mastering the art of calculation

within any given domain of mathematics as it stood during any particular historical milieu.

Further, Leibniz was not opposed to rigor per se.

Who were the “rigorists”? There were and are many. Leibniz named a number in his letters

when defending his methods against their attacks. It is too simplistic to associate such critics

with any particular philosopher though it is common to associate such attempts with adherents

of Aristotle or Averroes. Leibniz agreed with Aristotle on many points and sometimes

explicitly resorted to Aristotle to rebut Descartes. Leibniz says that Aristotle was the first to

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give demonstrations in Logic, “and we may say he was successful, but he was far from being

successful in the other sciences he treated.”349 Scholasticism owed its roots to Aristotle and

owed something to Averroes, but it also owed much to Thomas Aquinas’ purported defence of

Aristotle against Averroes’ alleged misinterpretation or misuse of Aristotle’s work and name.

By Leibniz’s time, mathematics included so much more than Averroes ever addressed

centuries prior. Further, there was no recognisable school of “Averroists” active in Leibniz’s

time.

Conclusion

Did Newton combine rigor such as that of Euclid and the scholastics with the wave of

Neoplatonic numerical mathematicisation? It might seem that Newton had the effect of

constraining the new Neoplatonic mathematics with an incarnation of Aristotelian reasoning,

namely that of Petrus Ramus as presented in Robert Sanderson’s Compendium of the Art of

Logic. However, we must deny such credit to Newton due to Kepler and Leibniz’s own rigor.

What, then, is different about the Neoplatonists?

Nikulin quotes Manin, “A good physicist uses formalism as a poet uses language.”350 Nikulin

explains, “since the language in poetry often says and suggests more than is intended, and, in

fact, negates and suspends the language by means of language itself, it may become

prescriptive, opening new possibilities for experiencing the world.” We would amend this

slightly to say that the good poet intends more than the language denotes, and already knows

what new possibilities they are seeking to describe and prescribe for further investigation.

Similarly, the physicist is not constrained by the limitations of formalism, but is required by

pragmatic circumstances to fit their ideas in formal language. What Nikulin touches on with

respect to the physicist and formalism, we would also say about the Neoplatonic

mathematician and formalism. In particular, a Leibnizian communicates the

metaphysical/ontological using the constraints of formal symbology.

Leibniz took exception to the rigorists demanding more from mathematical formalism than it

is fit to deliver. That is, he took exception those who criticised his calculus because it relied

on the infinitesimal which is a thing that might not exist. However, this may have been

because the ontological concept of the infinitesimal had not as yet been made sufficiently

precise. It may also have been because the symbology was not sufficiently advanced or

appropriate.

Nikulin may provide the key to an ontologically real mathematical object.351 However,

Leibniz was not concerned whether the infinitesimal was even ontologically real; to Leibniz,

it was merely a thought tool. In any case, the question of what an ontologically real

mathematical object is might tell us what is different about Neoplatonic mathematicisation

349 1685, Wiener, p.52 350 Manin, Y. I. Mathematics and Physics Trans. by A. and N. Koblitz, Boston-Basel-Stuttgart 1981, p.5 in

Nikulin, D. V. Matter, imagination and geometry: ontology, natural philosophy and mathematics in Plotinus,

Proclus and Descartes Ashgate, Aldershot and Burlington 2002, p.xii, n.17 351 Ibid., pp.70-74ff

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versus Newtonian mathematicisation. Nikulin was grappling with the question of how

mathematical objects which do not have physical existence can be used in physics.352 It is the

duality issue discussed in Chapter 3 in the context of Grosholz’s analysis of Leibniz’s

mathematics. To Leibniz, this is the distinction between the incorporeal domain of ideas and

active souls, and the passive domain of matter. Leibniz tied them together with his doctrine of

pre-established harmony.353

To Kielkopf who undertook a thorough review of Wittgenstein’s foundations of mathematics,

the mark of an “absolute platonist [sic]” is that they hold that “the domain of mathematical

objects themselves exist independently of minds.”354 As we will see in Chapter 7, Leibniz is

not this kind of platonist because Leibniz does not consider ideas to be real and only regards

them as able to exist in minds. However, he also regards them as having an objective truth so

that their qualities and properties are independent of minds although they have no existence

independent of minds. Further, he finds an actual correspondence between ideas and the

physical universe which is neither subjective nor dependent on sense perception implying that

there is a universe parallel to the physical universe in which ideas exist. Thus, we find a

mixedquality in Leibniz’s conception of mathematicals (a subset of “ideas”) such that in

certain discussions, he is platonist in the sense of believing there to be a non-physical universe

in which ideas exist, in other contexts he analyses and plays with ideas as if they were real

things, while in other cases still and especially in the context of monads Leibniz regards ideas

as never existing anywhere except in minds and usually only in God’s mind.

Are group theory, category theory and other modern forms of algebra Neoplatonic

mathematics or are they better described as positivist disciplines? Lie groups are

indispensable to modern physics, so they should be given at least as much credit as the

infinitesimal.355 We know that group theory has utility for the study of symmetry and pattern,

and has been useful in the practical sciences such as chemistry. Leibniz would have to regard

them as useful and therefore legitimate domains of mathematics. It is likely that Leibniz

would embrace them. In fact, it is hard to see how those who criticised the idea of the

infinitesimal could not direct the same criticism at Lie groups or any part of group theory.

What would Leibniz say about category theory which is an all-encompassing form of algebra

or meta-algebra?356 Any discussion of the philosophy of category theory must consider

Bourbaki, for the founding fathers of category theory (Eilenberg and Moore) were among the

handful of founders of Bourbaki. The contribution of category theory to diagrammatic

representation of abstract concepts would surely be admired alongside its contribution to the

understanding of mathematical structure.

352 Ibid., pp.x-xi 353 Leibniz, G.W. New Essays on Human Understanding Chapter X Book IV §§9-10 in Wiener pp.473-474 354 Kielkopf, C.F. Strict Finitism: An examination of Ludwig Wittgenstein’s remarks on the foundations of

mathematics Mouton, The Hague and Paris 1970, p.32 355 Stetz, A. Lie Groups in Modern Physics 1996, freely available online p.5 “There can be no question that the

modern theory of elementary particles rests heavily on the formalism of Lie groups.” accessed at

www.physics.orst.edu/~stetza/Lie.pdf 7 May 2011 356 This author’s Honours thesis was entitled “A categorical approach to universal algebra” Department of Pure

Mathematics, University of Sydney 2000 supervised by Dr Steve Lack. It is a relatively easy-to-read

introduction to category theory and universal algebra. Universal algebra was an even earlier form of meta-

algebra pioneered by mathematicians such as Whitehead.

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Chapter 6: Discovery and deduction

Introduction

There was a raft of mathematical thinkers in Ancient Greece who were able to reason both in

the abstract and in the concrete. Their work raises the question of the relationship between

formal reasoning and the physical world, and between abstract ideas and the physical world.

We become aware that there is a mode of thought that is not formal reasoning, but which is

structured and is worthy of the name reasoning. There was a searching for an order,

indefinable because it had not yet been found. It is recognised only when found, though the

thinker or scientist might be misled many times along the way. Formal reasoning is often not

the part of the search when breakthroughs occur, but is often added afterwards. We argue that

this searching or exploration is what Leibniz called Reason, and it is the primary tool in what

he called the Art of Discovery.

The “from where to which” of discursive reasoning is limited compared with learned

ignorance (docta ignorantia). This larger “God’s eye view” transcends discursive reasoning

and also allows us to see reason and harmony in the large. Because we can do this, we can

approach God’s mind and should seek to do so. It is from such a level that hypotheses are

formed ultimately to be tested by the structured observation of experiment.

Petrarca considers “learned ignorance” in the sense that Augustine uses it. To Petrarca,

“learned ignorance” is ignorance which is blessed and to possess it is to be enlightened by the

teachings of the Holy Spirit. To Petrarca, it is the highest kind of knowledge. To put it more

accurately, since it is more a mindset or an ideological and intellectual disposition, it is the

most amenable to (a) gaining new understanding of anything concrete and even (b) to

thinking.

Nicolaus of Cusa crystallised the Augustinian idea which had been picked up by Petrarca, and

we know that Cusa possessed a copy of Petrarca’s De Ignorantia. The book by Cusa applies

specifically to science and reason. In the debate with Wenck, Cusa sets learned ignorance

against discursive logic and explains why it is superior. Through De Docta Ignorantia, Cusa

explained why number is so important and guessed at why the Pythagoreans thought it to be

so. Cusa claimed that even comparative relation cannot be understood independently of

number, which means that number perhaps subsumes even the syllogism.

Since, relative to all that can be known, unknowing or ignorance is our state, and since as

Cusa says the highest knowledge we can attain is that of our own ignorance, then no original

knowledge can emanate from deduction because deduction uses only what we already know.

To have knowledge of our ignorance is to enter the larger, and vast, domain, of what we do

not know. Deduction does not work in this domain, but only inspiration and leaps of insight

can make any sense.

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Leibniz understood that deduction allows us to clarify points of contention using what we

already know. He regarded this as something that the common man could do when arguing

with his colleague over any mundane matter. This is very different, however, from the Art of

Discovery as Leibniz called it.

The Sarpian-Newtonian idea of conducting experiments and deducing from those experiments

is all very well too. This is not inconsistent with “physical Platonism” explained by Davies:357

Most theoretical physicists are by temperament Platonists. They envisage the laws of

physics too [like the principles of mathematics] as perfect idealized mathematical

relationships and operations that really exist, located in an abstract realm transcending

the physical universe. I shall call this viewpoint physical Platonism.

We do not advocate this brand of Platonism as metaphysically correct, or even as a

perspective of physics that Plato himself would have adopted. The question here is about how

those laws are discovered understood. Overemphasis on experiment does not allow the

investigator to address ironies or contradictions in what is observed, which can only be found

through thought and by entering the domain of our ignorance in science, mathematics and

metaphysics. In his learned ignorance discourse, Cusa is not describing a mystical process but

carrying on a conversation about human thought. We argue that Leibniz worked in this

tradition.

The art of discovery

In a letter, Leibniz poetically prefaces his recent discoveries with a gunpowder metaphor on

the light of discovery: “I am also sending you a little of the corporeal fire, which can well be

called a perpetual light, for when properly protected, it lasts many years without being

consumed. … It is easy to ignite gunpowder, either by the sun or through friction, after a little

of this phosphorous is mixed with it.”358

How does Leibniz come by this “phosphorous”? He gave us 10 maxims on the art of

discovery.359 These are to be distinguished from the art of reasoning for which Leibniz in the

same essay gave three maxims.360

To discover something new, we must – broadly speaking – follow these broad steps:361

1. Prerequisites: Consider all of its prerequisites or everything that distinguish it from

every other thing; this is its definition, nature or essential property.

2. Prerequisites of the prerequisites: Consider all of the prerequisites of each of its

prerequisites. This is true analysis or distributing the problem into parts.

357 Davies, P. C. W. “The Implications of a Cosmological Information Bound for Complexity, Quantum

Information and the Nature of Physical Law” Arxiv Preprint, p.2 Accessed at http://arxiv.org/ftp/quant-

ph/papers/0703/0703041.pdf on 21 July 2012 358 Loemker, p.249 (Letter to Huygens, 1679 around two years after Leibniz’s initiation into Huygens’

experiments with the [French] Royal Academy of Sciences) 359 c.1693, Wiener, pp.78-80 360 Ibid., pp.77-78 361 c.1693, Ibid., pp.78-80

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3. Perfect knowledge: When we have come to considering a few natures understood only

by themselves without prerequisites, we have reached perfect knowledge of the thing.

4. Single thought: Try to have this perfect knowledge in the mind so that we see it as a

whole in a single act of the mind. (This is “intellection”, the highest kind of the four

kinds cognition proposed by the Platonists, with which Leibniz agrees.362)

5. Prove our proposition: Now, nothing appears in the thing that cannot be accounted for

and nothing occurs which cannot be predicted in advance. This sounds difficult, but to

prove the single proposition that concerns us, which is usually all we need to do, then

it is readily done with the thing we are now acquainted with.

6. Start with the easiest: Always begin enquiries with the easiest things, or the most

general and simple things, like numbers, lines, motions, etc. depending on the kind of

thing we are trying to understand.

7. Find a natural progression: Proceed from easy to difficult things, attempting to find

some natural progression so we do not miss anything out.

8. Omit nothing: Try to omit nothing in our distributions and enumerations. Dichotomies

with opposites can help.

9. Catalogue of simple thoughts: The result should be a catalogue of simple thoughts or,

at least, of not very difficult thoughts.

10. Build up from the start: From the catalogue of simple thoughts, explain the origin of

things starting from their source in a perfect order and using a synthesis that is

absolutely coherent.

Leibniz may be referring to this process when nine years later he says that “my own views

have become fixed only after my considering all sides and weighing them well” summing it

up as “I have anticipated everything and gone through it in my mind”.363

According to the Platonists as Leibniz describes them, they were “not far wrong” in listing the

four kinds of cognition of the mind as:364

Level Called Or, in other words...

1 sense experience

2 opinion conjecture

3 knowledge demonstration which is reasoning by which

some proposition is made certain, and this is

nothing but the analysis of a truth into other

truths which are already known365

4 understanding intellection which looks into the connections

of truth in a single act of the mind

362 Leibniz, G. W. “Letter to Hansch on the Platonic Philosophy or Platonic Enthusiasm” 25 July 1707, in

Loemker, L. G. W. Leibniz Philosophical Papers and Letters 2nd ed. Reidel Publishing Company 1969, p.593 363 “Reply to Bayle’s Dictionary article Rorarius” 1702, Loemker, L. G. W. Leibniz Philosophical Papers and

Letters 2nd ed. Reidel Publishing Company 1969, p.582 364 Leibniz, G. W. “Letter to Hansch on the Platonic Philosophy or Platonic Enthusiasm” 25 July 1707. Ibid.,

p.593 365 Leibniz, G. W. “Letter to Herman Conring” 19 March 1678. Ibid., p.187

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Of these, the third bears some resemblance to item 2 “prerequisites of the prerequisites” and

the fourth (“intellection”) appears to be item 3 or the goal of “perfect knowledge” of the

thing. Further, to have perfect knowledge of a thing, everything arising from experience and

that can reasonably arise from conjecture must be consistent or explicable in terms of the

knowledge that has been attained, otherwise that knowledge is not yet perfect.

Intellection “belongs to God in all things but is given to us in simple matters only”.

The most striking thing is how much hard work is involved. The generality of the Leibniz’s

ten points indicates that the same rules apply whether one is designing a water pump,

addressing a legal problem, or working out the metaphysical foundations of science.

Neoplatonism is about having worked through these steps with the fundamental questions of

theology and metaphysics before working in the natural sciences. Having done that

background work in the largest context for natural science, one has a ready source of plausible

a priori hypotheses which are consistent with one’s theology and metaphysics with which to

start.

Leibniz explains in greater detail what is involved in science in a paper An introduction on the

value and method of natural science.366 Section subheadings in the paper include these which

are descriptive enough to be useful to list here among a number of others:

1. “Empirical physics is useful for human life and should be cultivated in the state”,

2. “A catalogue of experiments is to be compiled”,

3. “New experiments are to be undertaken at public expense, and only men outstanding

not merely in science but in virtue are to be placed in charge”,

4. “With the experiments are to be combined accurate and thoroughly extended

reasonings after the manner of geometry, for only in this way can causes be

discovered”,

5. “The most perfect method involves the discovery of the interior constitution of bodies

a priori from a contemplation of God, the author of things. But this method is a

difficult one and not to be undertaken by anyone whatever”,

6. “Some hypotheses can satisfy so many phenomena, and so easily, that they can be

taken for certain. Among other hypotheses, those are to be chosen which are the

simpler; these are to be presented, in the interim, in place of the true causes”,

7. “Analogies are useful in guessing at causes and in making predictions” and

8. “The method of reasoning from experiments resolves the phenomenon into its

attributes and seeks the causes and effects of each attributes”.

Discovery is often metaphysics

Discovery often takes place in the domain of metaphysics, and sometimes even in theology.

Leibniz wrote, “The a priori method is certain if we can demonstrate from the known nature

of God that structure of the world which is in agreement with the divine reasons and from this

structure, can finally arrive at the principles of sensible things. This method is of all the most

366 cc.1682-4 in Loemker, pp.281-9

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excellent and hence does not seem to be entirely impossible. For our mind is endowed with

the concept of perfection, and we know that God works in the most perfect way.” Due to the

difficulty of this method, Leibniz says that we must retain the a posteriori method, which is

the second method.367

The 15th to 17

th Centuries saw a Neoplatonic revival in the sciences. That revival brought with

it a conviction that “mere patterns and relational structures” (to use Grosholz’ words) are the

metaphysical “furniture of the universe”. To a Neoplatonist, there is no contradiction but,

rather, it is the order of things as derivable from Book VI of Plato’s The Republic.368 That

book argues that the philosopher has a method for finding answers which resolve existing

contradictions, though there is no guarantee that new contradictions will not be found. Book

VI is famous for introducing the “divided line” which is a classification of intellectual

exercise from the lowest level of conjecture and up to belief. Both conjecture and belief are

mere opinion, not knowledge. Next comes understanding and finally there is exercise of

reason. The latter two deserve the label “knowledge”. Opinions derive from the exercise of

the sense. Understanding includes mathematical thought, but is defined by Plato as images

and concepts of thought such as ideal squares and cubes. The highest level of the exercise of

reason is called dialectical thought, and it deals with ideas or ideals such as perfect beauty,

justice and goodness.369

Leibniz was conscious of the metaphysical dependencies of his infinitesimal calculus and of

its ancient roots. He recognised that Archimedes faced similar problems of political

correctness that he himself was facing:370

When my infinitesimal calculus, which includes the calculus of differences and sums,

had appeared and spread, certain over-precise veterans began to make trouble; just as

once long ago the Sceptics opposed the Dogmatics, … and such as Francisco Sanchez,

the author of the book Quod nihil scitur, brought against Clavius; and his opponents to

Cavalieri, and Thomas Hobbes to all geometers, and just lately such objections as are

made against Archimedes by that renowned man, Dethlevus Cluver.

Un-rigorous use of rigor

Leibniz notes a pattern through the republic of letters. He objects in particular to the use of a

requirement of rigor as a particular set of restrictions to criticise his method, as he appears to

regard such requirements as arbitrary or at least unjustified. Leibniz was well aware of the

opposing personalities:371

367 Ibid., p.283 368 Rouse, W.H.D. (trans.) Great Dialogues of Plato Signet Classic, New American Library a division of

Penguin, New York 1999, pp.281-311 369 Ibid., p.309 370 Child, J.M. (ed. and trans.) The early mathematical manuscripts of Leibniz; tr. from the Latin texts by Carl

Immanuel Gerhardt with critical and historical notes by J. M. Child The Open Court Publishing Company

1920, reprinted by the University of Michigan Library, p.145 371 Ibid., pp.145-146

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When then our method of infinitesimals, which had become known by the name of the

calculus of differences, began to be spread abroad by several examples of its use … a

certain erudite mathematician, writing under an assumed name in the scientific

Journal de Trevoux, appeared to find fault with this method. But to mention one of

them by name, even before this there arose against me in Holland Bernard

Nieuwentijt, one indeed really well equipped both in learning and ability.

Leibniz discusses the concept of infinitesimals and explains that, for example, “those things

that are found to be true about a parabola [treated in such a way] are in no way different, for

any construction, from those which can be stated by treating the parabola rigorously”.372

Nieuwentijt’s disagreements with Leibniz were not over rigor, but rather over the use of the

infinitesimal. First of all, Nieuwentijt believed that the infinitesimal was zero so any quantity

multiplied by it gave a product of zero. Second of all, there could certainly be no second order

differentials because these require the multiplication of an infinitesimal with another

infinitesimal. When opposing Leibniz on second order differentials, Nieuwentijt argues that

“there are no gradations in the infinite”.373 Nieuwentijt’s proofs assume a mathematics that is

based in what can be visualised. The fact that an infinitesimal could have a geometrical

meaning and could even be multiplied by another infinitesimal thereby obtaining a new

geometrical meaning is beyond the pale if one is trying to visualize the calculation. Of course,

Nieuwentijt’s objections to “gradations in the infinite” pre-empted Cantor’s theory of

transfinite numbers.

Archimedes had the same problem

Leibniz suggests that Archimedes faced similar criticisms, “Truly it is very likely that

Archimedes, and one who seems to have surpassed him, Conon, found out their wonderfully

elegant theorems by the help of such ideas [infinitesimals]; these theorems they completed

with reductio ad absurdam proofs, by which they at the same time provided rigorous

[Euclidean] demonstrations and also concealed their methods.”374 It may be that Gauss did the

same.375

Leibniz notes that Descartes too was aware of this. “Descartes very appropriately remarked in

one of his writings that Archimedes used as it were a kind of metaphysical reasoning

(Caramuel would call it metageometry), the method being scarcely used by any of the

ancients (except those who deal with quadratrices); in our time Cavalieri has revived the

372 Ibid., p.149 373 Vermij, R.H. “Bernard Nieuwentijt and the Leibnizian Calculus” Studia Leibnitiana 1989 Vol.21 No.1 69-86,

p.77 374 Ibid., p.149 375 “It is interesting to note that Gauss did not publish many of his ideas. It is commonly thought that this was

because he was a perfectionist and would only make his views known if they were above criticism. To that

end, he would not provide the intuitions behind his proofs, preferring instead to give the impression that they

came ‘out of thin air’” which, of course, they did not. Mathematics Illuminated Geometries Beyond Euclid

published by Annenberg Learner §8.4 Spherical and Hyperbolic Geometry accessed at

http://www.learner.org/courses/mathilluminated/units/8/textbook/04.php 4 June 2011

Page 115

method of Archimedes, and afforded an opportunity for others to advance still further.376

Indeed Descartes himself did so, since at one time he imagined a circle to be a regular

polygon with an infinite number of sides, and used the same idea in treating the cycloid; and

Huygens too, in his work on the pendulum, since he was accustomed to confirm his theorems

by rigorous demonstrations; yet at other times, in order to avoid too great prolixity, he made

use of infinitesimals; as also quite lately did the renowned La Hire.”377

All things and no things – at the same time

This two millenia context surpasses Grosholz’s interpretation of Leibniz.378 For Grosholz

referred to “the contradictory being of Leibniz’s infinite-sided polygons, at once continuous

and discrete, geometric and combinatorial, infinitary and finite”. Yet the “infinite-sided

polygons” were treated by Nicolaus of Cusa two centuries before Leibniz wrote about

mathematics. Cusa explained that a circle or “infinite-sided polygon” is of a higher order than

a polygon. It was relevant to the discovery process because the human mind is like a polygon

while God is the circle. Kepler wrote “in this one respect Nicholas of Cusa and others seem to

me divine, that they attached so much importance to the relationship between a straight and a

curved line and dared to liken a curve to God, a straight line to his creatures; and those who

tried to compare the Creator to his creatures, God to Man, and divine judgements to human

judgements did not perform much more valuable a service than those who tried to compare a

curve with a straight line, a circle with a square.”379

With God’s mind being of a higher order to human understanding, as a circle compared with a

square, so we must delve into our ignorance, and understand its quality in order to step closer

to the unreachable magnitude and quality of God’s intelligence.

The contradictions of “infinite-sided polygons, at once continuous and discrete, geometric and

combinatorial, infinitary and finite” were addressed by Cusa in his argument as to what God

is and is not, in considering God’s enfolding and unfolding. Cusa might as well be speaking to

Grosholz as “the Adversary” who was actually Johannes Wenck a leading Aristotelian

cleric.380 Cusa says that God is “absolutely, everything which is at all possible; and in this

376 Bonaventura Cavalieri (1598-1647) carried out seminal work with infinitesimals. It was often referenced

merely out of a sense of obligation by subsequent writers rather than because Cavalieri’s work bore any

relation to the later work. Cavalieri understood the infinitesimal as a fixed but extremely small quantity, quite

opposed to that of Leibniz. That is, Cavalieri’s infinitesimal appealed to common sense of the physical rather

than the ontological. Beeley, P. “Infinity, Infinitesimals, and the Reform of Cavalieri: John Wallis and his

Critics” in Goldenbaum, U. Infinitesimal Differences: Controversies between Leibniz and his

Contemporaries Walter de Gruyter, Berlin 2008, p.33 377 Child, J. M. (ed. and trans.) The early mathematical manuscripts of Leibniz; tr. from the Latin texts published

by Carl Immanuel Gerhardt with critical and historical notes Open Court Publishing Company, Chicago and

London, 1920 reprinted by University of Michigan Library, p.149 378 Grosholz, E. “Was Leibniz a mathematical revolutionary?” in Gillies, D. Revolutions in Mathematics Oxford

University Press, New York, 1992, pp.117-133 379 Duncan, A.M. trans. Kepler, J. Mysterium Cosmographicum Abaris Books, Janus Series Norwalk USA 1981,

p.93 380 Hopkins, J. trans. Nicolaus of Cusa Apologia De Docta Ignorantia 3rd ed., J. Arthur Banning Press,

Minneapolis, pp.481-2

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coincidence is hidden all apprehensible theology.” In particular, “in the mode of enfolding

[God] is all things but that in the mode of unfolding He is not any of these things.”

In De Ignota Litteratura, Wenck responds to Cusa:381

…if God (as he supposes the essence of the unqualifiedly Maximum to be) is the

precise measure of every essence, then how will it be the case that He exceeds,

incomparably, every essence? And how will the following [doctrine from]

Metaphysics X [i.e. book 10 of Aristotle’s Metaphysics] remain standing?: “In each

genus a first thing is the measure (metrum et mensura) of the subsequent things of that

genus; hence, in each genus there is a proper and precise measure.”

Cusa’s counter response is “the infinite is the most adequate measure of finite things—even

though the finite is altogether disproportional to the infinite.”382 Though “the impossibility of

there actually being an infinite line is shown in many ways in On Learned Ignorance” yet “by

the positing of an infinite line the intellect is helped to make headway toward the

unqualifiedly Infinite, which is Absolute Necessity of being.”

On a different track, Leibniz argues that if a proposition is not true in the infinitely small, then

it is questionable as to whether it is true in the finite. He explains that all of the propositions

that hold for the ellipse should hold for the parabola because regarded merely as an ellipse

with one focus infinitely far from the other. Similarly, if rest is regarded as infinitely small

velocity or infinite slowness, then whatever is true of motion should be true of rest regarded

as infinite slowness. Formulated laws starting to break down or show contradictions in the

case of rest when it is regarded as infinite slowness is a sign that those laws were wrongly

formulated.383

Does the infinite exist? It doesn’t really matter.

There are many relationships between Cusa and Leibniz, which have been explained by

historians of science.384 The purpose here is not to explore all of those relationships. However,

as regards the infinite and intellectual constructs in general, there are relationships that are

381 Hopkins, J. trans. Johannes Wenck De Ignota Litteratura 3rd ed., J. Arthur Banning Press, Minneapolis,

p.439

382 Hopkins, J. trans. Nicolaus of Cusa Apologia De Docta Ignorantia 3rd ed., J. Arthur Banning Press,

Minneapolis, p.482

383 Leibniz, G.W. “Letter on a general principle useful in explaining the laws of nature through a consideration of

the divine wisdom: to serve as a reply to the response of Rev. Father Malebranche” Nouvelles de la

république des lettres July 1687 in Loemker, L.E. Gottfried Wilhelm Leibniz: Philosophical Papers and

Letters D. Reidel Publishing Company, Dordrecht 1969 p.352 384 Hopkins says that Cusa’s likening of human minds to “living mirrors that mirror one another and all of

reality” was also adopted by Leibniz though Hopkins does not say where. The concept seems to be

encapsulated in Monadology since every monad perceives every other monad. Hopkins notes that in De

Docta Ignoranta II, 1 (97), Cusa says that the world is as perfect as it can be, which prefigures Leibniz’s

doctrine that this is the best of all possible worlds. Hopkins, J. “Nicholas of Cusa (1401-1464):

first modern philosopher?" in French, P. A., Wettstein, H. K., and Silver, B. (eds) Midwest Studies in

Philosophy Volume XXVI (2002): Renaissance and Early Modern Philosophy Blackwell Publishing, Boston

and Oxford, pp.16, 20

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relevant here. If the infinite and the infinitesimal are both infinites, then the method Leibniz

and others are using with infinitesimal reasoning are subsumed by Cusa’s understanding that

“positing an infinite line helps the intellect make headway” towards the truth. It is the positing

of possibilities or the musing about scenarios that pulls us forward, not necessarily the truth or

falsity of such hypotheticals.

We see that in Leibniz’s mathematics, the aim is pragmatism in the service of truth and utility,

not truth itself. For example, due to the facility of arithmetic progressions in simplifying

equations, to use them “is an exceedingly remarkable method”.385 Extending this to dy as it

depends on x, “by this artifice many excellent theorems with regard to curves that are

otherwise intractable will be capable of being investigated, namely, by combining several

equations of the same kind.”386 At the same time, it is not a game with an unimportant

outcome. If the method of causing a secant to approach the tangential did not yield an

understanding of the tangent, then an array of contradictions would have emerged and Leibniz

would have had to find another method.

Leibniz is frank on his pragmatism in the use of the infinitesimal itself, “whether such a state

of instantaneous transition from equality to inequality, from motion to rest, from convergence

to parallelism, or anything of the sort, can be sustained in a rigorous or metaphysical sense, or

whether infinite extensions successively greater and greater, or infinitely small ones

successively less and less, are legitimate considerations, is a matter that I own to be possibly

open to question”.387 He then goes on to address his “rigorist” critics directly and explain

what the infinite or infinitesimal are, as far as the question needs to be addressed, saying that

a quantity is such when it is “as great as you please, or as small as you please, so that the error

that any one may assign may be less than a certain assigned quantity”.388 In technical terms,

this does not contradict Cusa’s maintaining “the impossibility of there actually being an

infinite line”.

Leibniz declares that impossibility or otherwise of the infinite or infinitesimal is not

important:389

If any one wishes to understand these as the ultimate things, or as truly infinite, it can

be done, and that too without falling back upon a controversy about the reality of

extensions, or of infinite continua in general or of the infinitely small, ay, even if he

think that such things are utterly impossible; it will be sufficient to make use of them

as a tool that has advantages for the purpose of calculation, just as the algebraists

retain imaginary roots with great profit.390 For they contain a handy means of

385 Child, J. M. (ed. and trans.) The early mathematical manuscripts of Leibniz; tr. from the Latin texts published

by Carl Immanuel Gerhardt with critical and historical notes Open Court Publishing Company, Chicago and

London, 1920 reprinted by University of Michigan Library, p.97 386 Ibid., p.98 387 Ibid., p.149 388 Ibid., p.150 389 Ibid. 390 John Wallis geometrically explained negative numbers and square roots of negative numbers, treating

negative as the opposite direction of positive. Wallis geometrically constructs the square root of a negative

number by applying Pythagoras’ theorem to a right-triangle in mirror-image of another sharing the same

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reckoning, as can manifestly be verified in every case in a rigorous manner by the

method already stated.

Possibly in a continuation of the rigorist attacks on the infinitesimal, many of which stem

from its apparent non-existence, Boyer criticised Leibniz’s infinitesimal as lacking a precise

definition and said that it required Cauchy to make it precise. Boyer said that both Nicolaus of

Cusa and Nieuwentijdt, a critic of Leibniz, defined the infinite and the infinitesimal

unsatisfactorily.391 Leibniz maintained that it did not need to be any more precise than it was.

Moreover, is it possible that everything Cauchy used to make the infinitesimal precise,

purportedly, would several centuries before have required the same “leaps of faith” that

Leibniz’s calculus did?

Do Platonic ideas exist? It doesn’t really matter.

The method stated above (of arithmetic progressions extended to dy as it depends on x)

translates into the / method which was once taught in high school. Arguably, such “tools”

are examples of Platonic ideas, and Platonic ideas have given rise to much controversy. In his

statement about the calculus being “a handy means of reckoning” Leibniz stays outside that

controversy. For example, Cheyne and Pigden wrote that, “Mathematical platonists claim that

at least some of the objects which are the subject matter of pure mathematics (e.g. numbers,

sets, groups) actually exist.” They argue, “Either the dispensability of mathematical objects to

science can be demonstrated and, hence, there is no good reason for believing in the existence

of platonic objects, or their dispensability cannot be demonstrated and, hence, there is no

good reason for believing in the existence of mathematical objects which are genuinely

platonic.”392 However, Leibniz makes clear that it is irrelevant whether the infinite and

infinitesimal actually exist and, indeed, science can derive great benefit from them even if we

believe that it is “utterly impossible” that they exist. In any case, more than a century later,

Riemann proposed unboundedness as a postulate more general than infinitude.393

Cheyne and Pigden have implied that there is a distinction between platonic objects and the

“reality” of science. For Leibniz there is no distinction between the status of mathematical

objects and scientific theories which are putative scientific realities. This is not because

Leibniz regards mathematical objects as real but, rather, because scientific theories are as non-

real as mathematical objects even though scientific theories seem to the human mind to bear a

closer relationship to reality. At the same time, it must be noted that Leibniz’s conception of

vertical side. Incidentally, Wallis’ argument leads naturally to construction and use of x- and y-axes, which

bear Descartes’ name “Cartesian” today. Wallis, J. Algebra 1673, cap. LXVI (Vol. II, p.286) in Smith, D. E. A

Source Book in Mathematics McGraw-Hill: New York, 1929 p. 46ff 391 Boyer, C. The History of the Calculus and its Conceptual Development Dover Publications: New York, 1949

p.214 392 Cheyne, C. and Pigden, C. “Pythagorean Powers or a Challenge to Platonism” Australasian Journal of

Philosophy (1996) 74, 639-645. Leibniz may respond in the same way to Franklin, J. “Mathematical

Necessity and Reality” Australasian Journal of Philosophy 67(3), Sept 1989, 11-17. 393 Smith, D. E, A Source Book in Mathematics Dover Publications, New York 1959, quotes from Riemann’s

1854 dissertation Über die Hypothesen welche der Geometrie zu Grunde liegen

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platonic objects is not the same as those of mathematical Platonists because, for Leibniz,

platonic objects like all ideas are certain and inexorable but are not real.

What if everything we understood, or think we understood, about science were itself a

platonic object or corresponded to one? This is the obvious hypothesis for Nikulin to test in

his quest to understand how it is that, “Mathematical entities are to be associated with

empirical objects.”394 To do so, Nikulin must bridge the divide between the “platonic domain”

and the physical universe. On the one hand, Cantor appears to have thrown a spanner in the

works because his theory of infinite sets purported to understand the concept of an infinite

God. Chaitin calls it “mathematical theology”.395 On the other hand, such an investigation is

perfectly natural and potentially fruitful in Leibniz’s conception of science.

Metaphysical truths are at the heart of final causes which Leibniz emphasized are one of the

most powerful ways of understanding efficient causes. Recall that final causes are essentially

the workings of God’s mind in designing the universe.396 While the metaphysical tools used to

understand final causes do not exist, they are indispensable to minds that put themselves to

the task of understanding reality including scientific reality. For example, like the

Pythagoreans, Leibniz gives number the highest place when he says, “But there is nothing

which is not subordinate to number. Number is thus a basic metaphysical figure, as it were,

and arithmetic is a kind of statics of the universe by which the powers of things are

discovered.”397 (emphasis added) Given Leibniz’s outlining of the role of the concepts of the

infinite and infinitesimal, we can only conclude that he agrees completely with Cheyne and

Pigden when they say, “Numbers are needed to underwrite any conceivable causal order but

they themselves play no part in the proceedings. They provide a sort of metaphysical

framework for any possible physics — an indispensable, indeed, a necessary backdrop for the

causal show. But though there could be no causal structure without numbers, numbers are not

implicated in the causal shenanigans described by any science whether actual or merely

possible.”398

Thus, “the objects which are the subject matter of pure mathematics” are just as real as the

science to which they may or may not be dispensable. That “reality” is not corporeality or an

Empirical reality. This is an easy conclusion to reach if, like Leibniz, one is not prepared to

embrace Empiricism. This does not mean that Leibniz believed that mathematical objects

actually exists as mathematical platonists claim. Mathematical objects have the same

existential status as any other idea: they are not real and exist only as intellectual impressions.

394 Nikulin, D. V. Matter, imagination and geometry: ontology, natural philosophy and mathematics in Plotinus,

Proclus and Descartes Ashgate, Aldershot and Burlington 2002, p.xi 395 Chaitin, G.J. “The Search for the Perfect Language” a talk delivered at The Perimeter Institute for Theoretical

Physics, Monday, September 21, 2009. Text accessed at http://www.umcs.maine.edu/~chaitin/pi.html 15

April 2012 396 Leibniz, G. W., Specimen Dynamicum 1695 in Loemker, p.442 397 Loemker 1969, p.221 398 Cheyne, C. and Pigden, C. “Pythagorean Powers or a Challenge to Platonism” Australasian Journal of

Philosophy (1996) 74, 639-645, p.645

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Rigor is of service

Leibniz even grants that the rigorists have done a useful service as they have “discovered an

art of advancing and of deriving so many things from a few. If they had tried to put off the

discovery of theorems and problems until all the axioms and postulates had been proved, we

should perhaps have no geometry today.”399 It is the process that they have given us, even

though their axioms and postulates, and so the conclusions, are not true. Leibniz cites Euclid’s

unproven axiom that two straight lines can meet no more than once which project was

hampered by Euclid’s lack of a good definition of a straight line.400 Ironically, one of the

fathers of rigor, Euclid, assumed the infinitude of the line.401 However, writes Leibniz, “I

blame Euclid much less [than Descartes] for assuming certain things without proof, for he at

least established the fact that if we assume a few hypotheses, we can be sure that what follows

is equal in certainty, at least, to the hypotheses themselves.”402 Leibniz sees a broader

application of this lesson, for he writes, “if some careful and meditative mind were to take the

trouble to clarify and direct their [theologians’ and scholastic philosophers’] thoughts in the

manner of analytic geometers, he would find a great treasure of very important truths, wholly

demonstrable.”403

Science may use indemonstrables

Raynaud’s reading of Leibniz leads him to the same endpoint as we are reaching here. In

particular, that according to Leibniz “truth admits of degrees”, and “its discovery passes by

the way of logical analysis, and that even in theoretical matters it may sometimes be

reasonable to employ ‘indemonstrables’. Logic thus becomes once again the model for

science, because the first principle of necessary truths is the principle of non-contradiction. …

By the same token, he establishes a new continuity between science and the active life,

between knowledge and practical judgement, and between reason and faith. For if science

may employ indemonstrables, that also means that the initial absence of such principles does

not impede one from progressing on the path of reason, without having to ‘cast into doubt’

common beliefs.”404

Science and all thought worthy of the name Reason is about hypothesization, it seems, and

active use of hypotheses, until it becomes clear that a hypothesis contradicts something that

we know to be true through other means.

We now move away from considerations of pragmatism, and onto leaps of logic and the use

of metaphysics in physics.

399 Loemker, p.384 400 Wolfe, H. E. Introduction to Non-Euclidean Geometry Holt, Rinehart and Winston New York 1945, p.17ff.

See esp. pp.20-21 regarding Wolfe’s objections to Playfair’s Axiom. 401 Ibid., pp. 6, 8 402 Loemker, p.384 403 1686, Wiener, p.304 404 Raynaud, P. “Leibniz, Reason and Evil” in McCarthy, J. C., (ed. and trans.) Modern Enlightenment and the

Rule of Reason CUA Press Washington D.C. 1998, p.152

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Global architecture determines local mechanics

Franklin wrote that Kepler “aims to explain everything about the system of the heavens,

including facts of kinds that modern astronomy makes no attempt to explain.”405 So did

Leibniz, and like Kepler thought that it was not only perfectly reasonable to pursue such an

ambition but that ultimately that is the only valid quest for the scientist and metaphysicist

who, to Leibniz, were in almost identical professions.

Aside from all else, a kind of universal or physical morality, or morality of physics, is posited.

In c.1696, Leibniz wrote, “those minds in whom the imaginative faculty predominates …

believe that they need to use only mathematical principles, without having any need either for

metaphysical principles, which they treat as illusory, or for principles of the good, which they

reduce to human morals; as if perfection and the good were only a particular result of our

thinking and not to be found in universal nature.”406

The expression of that perfection and good is labelled by Leibniz as the architectonic nature

of things, or the way in which God acted in creating the universe. Leibniz is unambiguous on

the relation between the purpose of God in the very large, the mechanics of corpuscles, and

the relationship between religion and natural science. The dichotomy is from God as architect

to God as legislator, and there is really no dichotomy because they are both the same God.407

We quote from Leibniz’s Tentamen anagogicum which is extracted at greater length in

Appendix 2:408

...the smallest parts of the universe are ruled in accordance with the order of greatest

perfection; otherwise the whole would not be so ruled. It is for this reason that I

usually say that there are, so to speak, two kingdoms even in corporeal nature, which

interpenetrate without confusing or interfering with each other - the realm of power,

according to which everything can be explained mechanically by efficient causes when

we have sufficiently penetrated into its interior, and the realm of wisdom, according to

which everything can be explained architectonically, so to speak, or by final causes

when we understand its ways sufficiently. In this sense one can say with Lucretius not

only that animals see because they have eyes but also that eyes have been given them

in order to see...

The architectonic view is almost synonymous with a presumption of intention in the design of

everything in the physical universe.

405 Franklin, J. The Science of Conjecture: Evidence and probability before Pascal J. H. Press Baltimore and

London 2002, pp.150-1 406 Loemker, p.478 407 Wiener (a) efficient and final causes, first half of p.524 from “The Principles of Nature and of Grace, based

on Reason” 1714 second half of § 3, and (b) regarding God as architect, or maker of efficient causes, and

God as legislator, or maker of final causes first half of p.551-2 from Monadology 1714, §§ 89-90. 408 c.1696, Loemker, pp.477-9

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Intention in the large

Thus not only is the Creator most powerful and intelligent, but he acts with intention. Since

God created the universe and the universe “runs” without divine intervention, it would be

more accurate to say that God has designed an intention capability – indeed, imperative – into

the universe. That is, the universe itself “intends” for certain outcomes or, at least, for certain

tendencies or trajectories to be followed in the unfolding of events. At this stage, we refer to

this trajectory as “towards the Best”. For Leibniz, discoveries in natural science are bound up

with this presumption.

When doing science, philosophy or even when thinking about something to try to understand

it, Leibniz advises that we are greatly aided by first identifying whether we are considering

efficient causes or final causes. The former are the laws of nature or physics whereas the latter

are the appetition of souls. The appetition of souls are the tendencies or “desires” of the more

active part of the universe; these are the (incorporeal) monads with clearer perceptions to be

explained in detail in the next chapter. Neither the efficient nor final cause is adequate without

the other.409 We ultimately can better understand an efficient cause or how a process works in

the small if we also look to its final cause which, effectively, really is the intention of the

Creator in putting that process there or where that process fits in the Creator’s big picture.

The architectonic foundations of reality manifest in the ongoing functioning of the universe

including humankind within it moreso than in the initial act of creation. It is an anti-entropic

outlook on everything in the universe, including humanity.410 On the contrary, the usual

corollary of Clausius’ Second Law of Thermodynamics, often referred to as “the Second Law

of Thermodynamics”,411 is that the universe tends towards increasing entropy. The Leibnizian

corpus is therefore opposed to the Second Law of Thermodynamics.412 In any case, Clausius’

Second Law of Thermodynamics was only formulated in the context of particular heat

409 Ibid., Loemker p.588 middle of first paragraph 410 A detailed study of the Second Law of Thermodynamics is beyond the scope of this dissertation. However,

Hans Reichenbach’s explanation and proof is entirely statistical at the microscopic level. At the macroscopic

level it is entirely Empirical except where he is reasoning inductively from the microscopic. See

Reichenbach, H. The Direction of Time University of California Press, Berkeley and Los Angeles 1956,

pp.49ff and 145ff. Note that Leibniz was of the mind that time does not exist as an independent physical

reality; it is merely a creation by humans for ordering events. Similarly, pure space is merely an invention by

humans for giving objects position. Leibniz writes, “Time is the order non-contemporaneous things” and,

“Extension is the quantity of space” but “It is false to confound extension, as is commonly done, with

extended things, and to view it as substance.” 1715 “Metaphysical foundations of mathematics” in Wiener,

p.202 411 The literature on this topic is vast. For a summary, see http://hyperphysics.phy-

astr.gsu.edu/hbase/thermo/seclaw.html accessed 26 Feb 2012 412 It is not only the Leibnizian corpus that casts doubt on the Second Law of Thermodynamics. Prigogine says,

“...it must be recognized that the formulation of the second law seems to us today to be more a program than

a well-defined statement, because no recipe was formulated by either Thomson or Clausius to express the

entropy change in terms of observable quantities. This lack of clarity in its formulation was probably one of

the reasons why the application of thermodynamics became rapidly restricted to equilibrium, the end state of

thermodynamic evolution. For example, the classic work of Gibbs, which was so influential in the history of

thermodynamics, carefully avoids every incursion into the field of nonequilibrium processes (Gibbs 1975).”

Moreover, and noting that only irreversible processes contribute to entropy production, recently “a complete

change in perspective has arisen, and we begin to understand the constructive role played by reversible

processes in the physical world.” (emphasis in original) Prigogine, I. From Being to Becoming W. H.

Freeman and Company, San Fransisco 1980, p.78

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engines assumed to be closed systems. Whether there is any such thing as a closed system is

subject to debate. However, this question is well beyond the scope of this thesis.

This is seen in Leibniz’s “best of all possible worlds” doctrine – “everything in the whole

wide world proceeds mathematically, that is, infallibly” – as clearly as anywhere else in

Leibniz.413

Conclusion

A mathematics MSc thesis in the early 21st Century might seem an unlikely place in which to

debate some of the considerations addressed debated in this chapter. We are not undertaking

mathematical calculations, true. However, we are discussing in what context and to what end

mathematical work should be done. Mathematical work is always done with philosophical

and metaphysical assumptions. Scientific work, especially basic research, can only benefit

from at least being aware of what one’s assumptions are so that they can be questioned. The

entire direction of a scientific or mathematical career could be changed by an awareness of

the metaphysical foundations on which a researcher is building their work.

413 “On destiny or mutual dependence” in Wiener 1951, p. 571

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Chapter 7: Science by thought, and reality and substance

Introduction

It is often thought that modernity is synonymous with an aversion to the supernatural. Further,

the common stance is that belief in God is unscientific or, at least, something that bears no

connection to science. For Cusa, Kepler and Leibniz, this was not the case. For them, doing

science was coming to understand God. This was not just a matter of labelling their

discoveries as a deepening of their understanding of God’s Reason. The process of scientific

enquiry was benefited by seeking to better understand God. In fact, the act of scientific

enquiry could not be undertaken without thinking about God and God’s relationship to the

universe. Leibniz held that sense perception has limited usefulness in discovering truth and

that truth is discoverable only by the mind. Moreover, Platonic ideas when known can be used

as tools by the mind.

Were we only able to “know” what our senses tell us, God would not exist for us since God is

not manifest to the senses. In that case, there could be no harmony or meaning, only

coincidences. But our reason tells us that there is harmony which cannot be accidental. Cicero

argued this in De natura deorum with the analogy of the barbarians observing a ship of a size

and complexity they have never before seen and slowly realising that it was made by

intelligent minds. In the analogy, the barbarians represent thoughtful humans and the ship

represents the physical universe. If there are only coincidences, we must give up hope that

reason can ever be of use, and rather deduce only from sensory observations. Platonic ideas

cannot be discovered within such a framework. Furthermore, we only discover the harmony –

that is actually there – using reason. Once we allow that reason, then we see a great deal else.

It does not make sense that there would be harmony in some things but randomness

elsewhere. From here we get the principle that if only we could see things “in the large” we

would see the harmony everywhere. Leibniz took Kepler’s harmony further, beyond the study

of the solar system into all things, philosophical and metaphysical, and into all fields of

enquiry.

The empirico-deductive line of thought was largely atheist, though some thinkers – like

Newton adopted a conception of God consistent with the positivist science they were

constructing. Theistic metaphysics gives rise to a scientific method that is more permissive in

the range of thought allowed and more powerful in pushing the envelope of human

understanding through progressive grasping of principles that govern the universe. Leibniz

would argue that it is not only more permissive but necessarily more correct. As we shall see

in Chapter 7, Kepler argued the same.

In this chapter we will describe and discuss Leibniz’s framework for reality, including God,

substance, the universe as a whole, the components of the universe and how these components

interact. There are many references to Leibniz’s Monadology.

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Science by thought

Leibniz’s writings lead us to the conclusion that all science can be undertaken in the mind.

Parkinson asks, “Is it true to say that Leibniz, in his science, relies wholly on a priori

arguments?”414 answering “Yes” for the most part, but not exclusively as Leibniz leaves room

for observation and induction from observations.415 We hope to flesh out Parkinson’s answer.

Science is done by investigation and reasoning about metaphysics, mathematical rules and

other ideals. Science done in this way seeks to understand the mind of God, ultimately. Thus,

theology is prominent in Leibniz’s framework.416 Farrer says, “If we condemn Leibniz for

writing physical theology, we condemn not him but his age.”417 However, Leibniz makes it

clear that it is a conscious contention of his own that God must be a central consideration,

rather than something he has imbibed from the zeitgeist.

It has already been mentioned that in Theodicy Leibniz defended the daring endeavour of

seeking to understand the mind of God against detractors, and supported others who

encouraged and joined the quest. While Leibniz accepted Cusa’s doctrine that in ignorance the

soul finds its repose, nonetheless what Christian faith commands does have reason at the back

of it which is comprehensible by men.418

While experiment is useful in checking our reasoning, it is not necessary by force of reason. It

is practically necessary because our conceptions and thoughts are generally indistinct and

confused. Occasionally, a human mind comes along which is clear and distinct, and teaches us

how to think and in so doing gives an entirely new set of ideas. Plato and Jesus Christ would

be examples. The “believe it when I see it” mentality is nothing but a popular choice for

perception over thought.419 Indeed, the soul itself and its function of thought are not furnished

by the external senses.420 That Einstein was thinking in this vein would be evidenced by the

quote anecdotally attributed to Einstein, “I want to understand his [God’s] thoughts. The rest

are details.”421

Universal characteristic

The power of a priori reasoning is why the Universal Characteristic, or calculus of ideas or

Lingua Philosophica (“Language of Philosophy/Logic”), is the one of the most important

414 Parkinson, G. H. R. “Science and metaphysics in Leibniz’s ‘Specimen Inventorum’” Studia Leibnitiana Vol.

6, 1974 p.4 415 Ibid., p.15 416 Leibniz writes, “Herr Dreier of Königsberg has aptly observed that the true metaphysics which Aristotle

sought, and which he called [Greek: tên zêtoumenên], his _desideratum_, was theology.” Theodicy PG

edition 2005, p.244 §184 417 Leibniz, G. W. Theodicy Project Gutenberg edition 2005, p.28 accessed at www.gutenberg.org 418 Ibid., §§48-51, pp.101-102 419 §5 in Loemker,p.638 420 Loemker, p.556 start of 2nd last paragraph 421 At http://web.ceu.hu/yehuda_einstein_and_god.pdf accessed 30 Oct 2010, §9, pp.4-5. This is quoted as a

statement by Albert Einstein in many locations, but we have been unable to find the primary source.

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undertakings.422 While Brown notes that Leibniz made little apparent progress towards it,423

Leibniz had a clear conception of its nature, what it would be able to achieve and why it was

possible. However, it may be that Leibniz’s work on the calculus and especially in logic were

themselves strides achieved toward the universal characteristic.

Antognazza says that the characteristica universalis was a part – though a large part – of a

scheme for all areas of human thought and endeavour from science and technology to law and

religion which Leibniz called the scientia generalis. Leibniz wrote an array of articles towards

this goal. For example, in a series of logical texts written over 1678-1684, Leibniz outlined a

logical calculus whose structure remains valid independent of the contents assigned to the

letters used in the argument such as, to use Antognazza’s example, a for “animal” and b for

“rational”.424 With it, as well as many day-to-day uses, we could conduct a priori science.

This is not “discovering the mind of God” per se, which is impossible according to Cusa,

since truths, physics and all else but God are distinct and independent from God, as Leibniz

explains in “Reflections on the doctrine of a single universal spirit”.425 It is also impossible

according to Leibniz.426 Nonetheless, the more clarity we can achieve, the better off we are; in

particular, the more useful our hypotheses will be.

Leibniz lamented that the art of discovery was little known outside of mathematics and said

that it should exist in systematic form for all domains of knowledge.427 Developing a calculus

of ideas might start with the Platonic dialogues. Leibniz’s own development of the

infinitesimal calculus might provide ideas on how to start, albeit there would necessarily be

important differences.

Dream vs reality, and substance vs phenomena

Leibniz distinguishes body from a phenomenon in a coherent dream.428 On the contrary,

Leibniz also said there is value in the Platonic perspective that we wake up on death implying

that death is more real than life.429 Confirming Leibniz’s dim view of how much truth is

directly discernible from what is experienced in life, he explains that he can demonstrate

experimentally that all the perceivable properties of bodies are apparent only. This does not

mean that there are no real bodies. It is just that what we perceive about them is misleading.

Bodies are real when they have substance. Such bodies may act or be acted upon, whereas

bodies that are not real cannot act on other bodies and cannot be acted upon. Bodies that are

not substantial are merely phenomena or, at most, are aggregates of true bodies. A coherent

dream has phenomena but not substantial bodies, and a phenomenon is defined by the act of

observing it not by the substance that it may or may not include. A substance has active

422 Leibniz, G.W. “Towards a Universal Characteristic” 1677, Wiener, p.17 423 Brown, R. C. Leibniz, unpublished, Chapter 11 “Epilogue” p.167 424 Antognazza, M.R. Leibniz: An intellectual biography Cambridge University Press 2009, pp.241-243 425 1702, Loemker, pp.554-560 426 Ibid., §14 p.640, and p.641 5th, 4th and 3rd last lines 427 “Precepts for advancing the sciences and arts” 1680, Wiener, p.49 428 At http://plato.stanford.edu/entries/leibniz-mind/ section 1 second last paragraph, accessed 30 Oct 2010 429 Loemker, pp.364-5, i.e. last paragraph of p.364 spilling over to first paragraph p.365

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metaphysical power insofar as it expresses something distinctly, and passive power – i.e. the

ability to suffer being acted upon – insofar as it merely expresses something confusedly.

There are infinite degrees between. Here we see that Leibniz has defined the power of a thing

by its clarity of expression. To Leibniz, as we will see in his definition of ideas, clarity

includes consistency with all else that is real in the universe.

What is real?

The mind is part of reality, but it also sees reality imperfectly. By contrast, God’s mind

perfectly sees all of reality, i.e. all soul and body monads, and all ideas and their implications

on reality.

The “really real” are the simple substances or created monads which once existing endure

always, as well as God himself.430 So: (i) God and (ii) simple substances also known as

created monads also known as souls comprise all that is real. These do not exist in the mind of

God. That is, the “verities” (universal truths or ideas) are not the result of God’s will, contrary

to Descartes.431 Harmony itself is a thing separate from God, but harmony is perceived –

albeit that it is an idea – so it is not really real either. God creates things in conformity with

such because to do so is the highest and best way of doing things. Beauty is something

separate from God but only God makes it possible because everything that gives rise to it in

reality (viz. monads) comes from God.

Monads are real

With the monad concept, Leibniz is following his own advice in the principles of discovery in

breaking things down to their most fundamental parts. However, monads are not just atoms or

quarks, for they have knowledge of one another and of the entire universe. Thus, they each

express the whole as well as being the parts. If we regard the entire universe as an organism,

then monads are like cells in that each cell has DNA with an encoding of the entire organism

(i.e. the entire universe) while also “knowing” its role in the organism.

A “created thing” is a created monad.432 Monads are actual things, i.e. they are “existing”.433

The monad is nothing but a simple substance, or a substance without parts, which enters into

compounds.434 The soul of humans is simple.435 The rational soul is the “substantial” part of

man.436 The physical form of man comprises trillions or more of body monads. Those body

monads exist and are substantial, but the physical form is passing, temporary and, in any state,

430 Ibid., p.592 last para. 4th line 431 Theodicy, p.244 §186, p.428 §21 accessed at www.gutenberg.org 432 Monadology §49 in Latta, p.245 433 Ibid., §8 p.220 434 Ibid., §1, p.217 435 Ibid., §16, p.226 436 1705, Loemker , L. E. Gottfried Wilhelm Leibniz: Philosophical Papers and Letters 2nd ed. D. Reidel,

Dordrecht Holland 1969 p.586

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is an idea only. Thus, it is insubstantial. Even as an idea, it can accurately only be conceived

in the infinitesimal and this is only an idea. In fact, it is never existent or being, and is only

ever becoming.

In explaining monads in Monadology, Leibniz referred to substance in a particular way suited

to his conception of monads. This is sensible because, as Leibniz explains it, all substance

comprises monads; there is no substance that is not “made” of monads, and this includes

substance that is not intangible such as the soul and even such as God. Passive substance,

which includes the constituent simple body monads of a human’s physical form, is simply in a

prolonged unconsciousness.437 Yes, the soul is a substance and no substance is perishable in

nature.438

Most monads come in pairs – body and soul – wherein either or both elements of the pair may

be a compound monad.439 They cannot be the same monad because one is a compound monad

and thus destructible whereas the other is not. One is relatively passive, the other active. Yet

they act in harmony. This is a “pre-established harmony”.440

Each monad is aware of every other. There is an inter-communication between all monads and

thus between all things, so each body feels the effect of all that takes place in the universe.

Thus, it would be possible to “read in each what is happening everywhere, and what has

happened and shall happen, observing in the present that which is far off in time as well as in

place.”441 Latta writes that this inter-communication is a symbol of pre-established

harmony.442 It is not clear why Latta uses the term “symbol”. Arguably this is not what

Leibniz means. In formulating the pre-established harmony, we do not know whether Leibniz

had any purpose other than to bridge the gap between the realm of final causes and that of

efficient causes, or between the immaterial and the material. The universal awareness of each

monad is a property of monads. A harmony, on the other hand, is an idea which governs

things from outside of themselves.

There must be body monads without a soul which are entirely passive, and spirit monads

without a body. However, the question of being soulless or bodyless is one of degree for

Leibniz posited a continuum in most metaphysical matters he considered. Neither generally

exists in the natural order of things and Leibniz does not discuss them in detail.

The soul (part) is not divisible into an active eternal part and a passive temporal part as

Averroes believed.443

437 Monadology §14, p.224 438 Ibid., p.225 mid-footnote 25 439 See esp. the 9th and 10th last lines of the 2nd para. p.590 of Loemker, and the overall 1702 essay on universal

harmony Loemker, pp.574-591 440 Ibid., p.587 441 Monadology §14, p.251 §61 442 Latta writes, “the material action and re-action throughout the universe, such that a change at any one point

affects every other, is a symbol of the Pre-Established Harmony among the Monads.” Ibid., p.251 footnote 96 443 1702, Loemker p.554 2nd paragraph

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Immaterial souls exist

Leibniz calls Epicurus and Hobbes’ doctrine of material souls an evil one. Leibniz also wrote

that they have extended to humans what the Cartesians have held for animals, which is also

incorrect.444 Leibniz also says that it is pernicious to deny the immortality of souls.445 This

brings Leibniz into opposition with Pompanazzi and Sarpi.

We will see later that active or more perfect monads (souls) and passive or more imperfect

monads (bodies) are all that exist aside from God. It is consistent with this that Leibniz often

wrote that the purpose of the universe is to help intelligent souls get closer to perfection and

felicity. According to Leibniz, this is the paramount goal of God.

The nature of ideas

Ideas exist in our memory, indistinctly, and can be brought to the fore as Plato showed in

Meno. God too has many ideas, but perceives/thinks them distinctly and all at once as Leibniz

encourages humans to do in “the art of reasoning well”.446

God Body monad Soul monad

Perfect Imperfect Less imperfect

Active Passive Less passive

Immaterial Material Immaterial

Memory No memory Memory Together, Memory and

Perception are Sentiment. Knowledge Perception Perception

Will Appetite Appetite

Figure 3: Some qualities of God and substances

Time, distance or length (i.e. “extension”), motion, the continuum and numbers express only

possibilities.447 They are ideas at the simplest level; they are primary. Leibniz recalls that

Hobbes described space as a “phantasm of the existent”448 without disagreeing. A phantasm is

an image as if in a dream. Dreams do not exist anywhere except in the mind of the dreamer;

dreams are not real. The definition of real is that which conforms to metaphysical principles

and mathematical rules.449 It is only through such that we know that we are not dreaming; that

is, that our experience is not a mere figment of (or a mere image in) our mind. This is because

our perceptions are imperfect and indistinct; if our current reality was a creation of our minds,

then there would be inconsistencies everywhere and there would be measurable discrepancies

from ideals. In any case, there is only one reality and it is not just a “coherent dream”.450

444 Ibid., p.577 445 Ibid., §4 Loemker p.638 446 Inference from Monadology, p.247 §53; “On wisdom” c.1693, Wiener p.77 447 Loemker p.583 448 Loemker p.583 449 Loemker p.583 last 20 lines 450 At http://plato.stanford.edu/entries/leibniz-mind/ section 1 second last paragraph, accessed 30 Oct 2010

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More accurately and specifically, extension is the order of possible coexistence whereas time

is the order of possibilities which are inconsistent (i.e. cannot coexist) but which have a

connection through (continuous) events. However, space and time themselves are indifferent

to what content is put into them, just as numbers are indifferent to what they enumerate. Here,

Leibniz is distinguishing the real from the non-real. An ideal is an idea all the same.

Leibniz consistently fails to enlighten us on where ideas exist probably because he would

maintain that an idea is a potentiality at most. It does not exist anywhere. In his characteristic

style, he would likely dismiss the question as nonsensical. For a truth does not exist

anywhere, it simply has the potential to be used in governing the behaviour of passive

substance because it is the best pattern of behaviour. An idea is not real. For Leibniz, the non-

reality of concepts and ideas dates back to his bachelor’s dissertation published when he was

17 and written under the direction of Thomasius.451 While the intelligible world in the divine

mind is the region of ideas, the ideas are not real. The divine mind knows them, and it does

not need to work ideas out (i.e. find them) or general them for it sees all at once.

In a book entitled Strict Finitism, Kielkopf undertakes a thorough analysis of Wittgenstein’s

foundations of mathematics. There, Kielkopf says that an absolute platonist (sic, small “p”)

believes that mathematical objects have their own independent existence. Strictly speaking,

Leibniz is not platonist according to this definition because, to Leibniz, ideas are not real and

do not “exist” in any domain nor even in God’s mind or our own minds. Ideas might be

perceived in our minds, but they do not exist there. An idea does not exist to be perceived but,

rather, the idea is itself a perception. When the mind perceives an idea, it is, in part, creating

an impression on itself and, in part, receiving impressions from the physical universe. Note,

however, that the only mind which ever perceives an idea is God’s mind. Humans can only

ever approximate ideas.

To Leibniz, “real” includes physical and metaphysical. Though he says ideas are not real, it is

clear that ideas played a role in God’s mind during the design of the universe and they

certainly occupy the activities of human minds. This does not mean that ideas exist in God’s

mind or human minds. Concepts, too, play a role in human minds, though concepts have

internal inconsistencies causing them to fail to qualify as ideas. Nor do concepts exist in

human minds. This is because to be a mental impression alone is not to exist.

There will now be some discussion involving ideas, hypotheticals and hypotheses.

Hypotheticals are treated as atomistic propositions or concepts, such as the existence of a

perfect square or just the concept of a perfect square. A hypothesis is a set of concepts that are

more widely encompassing of a process, formulated with the intent of explaining that process.

The usual meaning of hypothesis as a precursor to a theory of some physical process, force or

phenomena is useful too. There is usually some unifying thread between the concepts in the

hypothesis. This high level of abstraction is sufficient for what follows.

451 “In the course of his analysis he shows himself a Nominalist. To Leibniz nothing exists independently of

individuals. Common properties shared by individuals do not actually exist in re; they are purely creations of

the mind.” Brown, R. C. Leibniz unpublished, Chapter 4, pp.32-33

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An idea has the same reality as a hypothetical or a concept. None of them exists in the

physical universe. The geometrical concept of a perfect square is a hypothetical. Yet a perfect

square can never be realised in the physical universe and so it is not an idea. Nonetheless, it is

useful in understanding the universe because the universe is designed in the best possible way

and so there is an order to it. Thus, understanding the best possible involves the use of ideals

such as geometrical ideals and other mathematical ideals. Mathematics as the study of

structure presumes that there is structure in the universe or underlying the universe. Really, a

hypothetical can be regarded simply as a concept formulated with the purpose of aiding in

understanding the universe and therefore it probably should and usually does have some

structure to it.

A hypothetical is just an intellectual impression in the mind, and the mind is capable of

formulating nonsense which could never be realised in the physical universe as well as

concepts which can never be realised but which are nonetheless useful to us. A thought of a

thing that can be realised is no more real than a thought of an impossible thing – both are

merely a thought or mental perception. A concept is promoted to the status of an idea if it is

internally consistent and consistent with all else that must be realised in the universe for the

universe to be the best possible. Ideas do not exist in the immaterial domain of souls, but they

do define the best possible – indeed, the only – way of organising the universe. So where do

ideas exist? Again, ideas are only perceived by minds, yet they are perceptions that can be

manifested in the physical universe. Were hypotheticals and thus hypotheses prohibited in the

conduct of science, we would not be able to attempt to work towards ideas and thus predict

and control how the physical universe works, except in a haphazard and accidental or

serendipitous way. The benefits of mathematics and physics would be denied to us.

The applicability of ideas

We will use the term ideals and ideas interchangeably. However, the term “ideals” will tend to

emphasise metaphysical principles and mathematical rules all of which are ideas themselves.

Leibniz sometimes regards the laws of physics as comprising metaphysical principles and

mathematical rules. On the other hand, the term “ideas” encompasses all truths including

ideals.

Ideas or ideal things – since an idea only qualifies with that name if it is clear and non-

contradictory and is therefore a derivative of ideals – express possibilities. They are not

actually real.452 However, they are imprinted on or remembered by our soul’s memory which

may or may not be infinite though it can comprehend the infinite though in fact it only ever

does so in an indistinct way.453 X being remembered by the memory does not mean that X

exists there. “Something mental” only designates “the possibility of parts, not something

actual”.454

452 1704, Loemker pp.535-6 453 1702, Loemker p.583 454 1704, Loemker p.536

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Considering numbers, an idea is different from a possibility but it is a characteristic or

denotation of an aspect of a possibility since no number can ever really exist. Yet ideals

govern passive substance and the passive part of substance that has active and passive parts,

for everything is composite and nothing actual is purely active or passive. The most active

souls and God choose to create in conformity with ideals because that leads to the greatest

harmony and leads to the greatest felicity for all souls. Deluded souls (including humans

limited in understanding) create in a way that contradicts ideals and, thus, in a temporary way.

However, God has designed things so that something good comes from perceptions and

appetite based on delusion or incomplete understanding (or “silliness”). Relatively passive

souls like those of ants are mostly governed by laws and cannot choose. Humans with

understanding can choose even better than nature can because nature passively unfolds matter

in accord with ideals, which is different from the proactive creation undertaken by an active

or less passive monad.

It is only through the impact of principles/ideals on passive substance that we can ever really

“see” them. Yet the active/experienced mind can think things through and “see” what is right

without it having to manifest in the world of substance. Note that the “world of forms” is

nothing but mental images or perceptions in the interior of monads. Thus, ideals are

significant although they can never be touched even by God. Ideals can only subsist as

images/impressions in the mind, including in God’s mind. At the same time, they only have

any effect due to the universe of passive substance. The world provides the opportunity for

minds to test their notions and to draw ideas out.

How can it be that a geometrical straight line or triangle do not exist anywhere? They are

impressions in the mind which we can describe unambiguously and so can convey to another

mind which will then also have the impression in their mind. The impressions will likely not

be identical though they will be very close, particularly between the minds of, say, geometers

who conduct proofs with them and so force themselves to coincide almost entirely in their

conceptions or notions of these ideas. Testing our notions in the physical world also aids.

The Aristotelian view of ideals seems to agree with the Leibnizian view because (Platonic)

ideas are apparent only in the created (physical) universe. However, a mind can find and

“know” ideas whether or not they seem to be available to sense perception by their

correspondence to phenomena in the universe.455

God does not need to “see” ideas and probably does not perceive them one at a time like

human minds do. God can grasp not only the entire actual universe in one act of his mind, but

also all possible universes in one act of the mind. His “perception” is indistinguishable from

his mind in perspicacity. The concept of sense perception makes little sense for God.

For humans to perceive something via the senses usually generates a more distinct mental

impression than does conceiving something purely through an act of the mind. For humans,

455 For example, geometry would exist without the universe, but it would have no object. As Leibniz puts it, “For

it is, in my judgement, the divine understanding which gives reality to the eternal verities, albeit God's will

have no part therein. All reality must be founded on something existent. It is true that an atheist may be a

geometrician: but if there were no God, geometry would have no object.” Theodicy p.243 §184

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no act of the mind is pure but is always bound up with a memory of a sense perception to a

greater or lesser degree. But God has created souls anyway from which the physical universe

results because it is his nature to create and to do so in a way that is the highest and best and,

to a mind that can grasp it (and only God can do so fully), the most beautiful.

Ideas and “the Best” are outside all that exists

If ideas required the world to be perceived, by being realised in objects, substance, radiation,

etc. then God would need the world to guide divine decisions which is patently absurd since

the Creator of the very laws of the universe does not need to refer to the Creation that results

from his thoughts. For example, harmony is an idea. The fact that there may be harmony

among ideas or a “harmony of ideas” suggests that ideas are independent of the world.

However, on the other hand, the meaning of the Best is intertwined with the universe which

God has designed to be the Best.

There is no domain of principles by which, if we were to grasp it, we would understand the

universe. The universe is what it is, and our minds’ development of ideas is nothing but us

(humans) trying to comprehend it. Ideas are indispensable as intellectual tools because the

universe is perfect and ideas have the necessary condition of perfection that they are internally

consistent with themselves and externally consistent with all other ideas and, indeed, with all

of reality. It could almost be said that ideas describe the real universe. There is a

correspondence can be seen between mathematical frameworks and the physical universe,

which Figure 4 presents in schematic form.

The apparent governance over actual things by ideas

The utility of mathematical thinking is not diminished by the fact that it is not real. This is

because actual things cannot escape its rules as Leibniz put it.456 While ideas allow us to

understand how phenomena must have happened and how phenomena will happen, they are

only useful because they are non-contradictory. Where a conception is confused then its

power is merely of passive or primary matter, otherwise it is active.

Distinctness of perceptions gives active power, and confusedness gives passive power which

is attributed to metaphysical matter or materia prima.457 So distinctness of ideas is paramount

in monads. The universe comprises only monads, but most are effectively asleep, indeed

comatose, or passive.

For example, though extension is an idea, it is of great importance in physics. Leibniz’s entire

discussion of Aristotle’s primary matter takes place in the realm of ideas not once referring to

monads (which alone are real, aside from God) or their equivalent.458

456 Loemker p.583 457 Loemker, p.365 last paragraph 458 Loemker, pp.536-7

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Figure 4: Ascendence in the geometrical part of idea systems of improving perfection towards

one that corresponds to “the Best”

The relationship between ideas and actual things

Rather than saying that actual things cannot escape the rules of mathematical thinking, it

would be more accurate to say that minds attempting to understand the universe cannot escape

its perfection, and so will be drawn to mathematics. So the converse is true, that the rules of

mathematics cannot escape actual things.

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Creation of additional mathematical structures that bear no relation to observed phenomena in

the physical universe is useful and beneficial. In particular, if the conceptions so developed

bear no self-contradictions or contradictions with other truths – i.e. are ideas – then they

furnish readymade hypotheticals which may help close gaps in understanding that may arise

from paradoxes in future empirical observations.

If Leibniz is so adamant that ideas are not real, then why do we need them? After all, in

becoming a well-known mathematician, Leibniz spent a great deal of time with ideas, or

putative ideas. It is certain that the human race would little more than an advanced mammal if

we were to abandon our quest for ideas. Ideas are an intellectual abstraction and resolution

that are essential for these among many other reasons:

1. Prediction of future events/phenomena

2. Committing to a record and communicating from one person or group of people to

another, and from one generation to another

3. Connections between ideas connect seemingly unrelated phenomena

4. Machine-building

5. Computer programming, which is a specific case of machine-building.

Indeed, this discussion could quickly expand beyond ideas into concepts and into thought

itself. In fact, the above five points relate primarily to concepts because most or all or what

we think we know to be ideas will in future generations be found to be incorrect and to be

merely concepts. A successful hypothesis is an idea whereas an unsuccessful hypothesis is a

conception. Both ideas and conceptions are examples of thoughts.

Inexorable necessity created by the requirement of “the Best”

Necessity arises in deductive processes from presumption, axioms or postulates. Necessity in

what is manifested in the physical universe is a result of something being part of “the Best”.

The concept of the Best does not arise merely as a thing in isolation (like a triangle with angle

sum 180°) but as a process of events over time which – by the definition of an idea – connects

with everything else in the universe. It is hard to see how an idea could ever be conceived

without having the ability to perceive the entire universe and all of its processes over all of

time in a single thought. This is not even equal to the ability to perceive all ideas in one’s

mind at once in a single thought, and it is this which would be needed for the design of the

universe as a whole. One would also need to know what the Best is, and either create that (in

one’s mind, first) or choose it from multiple possibilities or options. On the other hand, rather

than this “brute force processing power”, which would require no effort for God in any case,

it may be that the Keplerian search for harmony would be more accessible and more fruitful.

That is, start with what we know has harmony and beauty, and expect to find that in the

physical universe.

It is in these considerations that the relation between God’s mental universe, or the domain of

ideas, and the physical universe is found. The connection with our intellectual/mental world is

similar, but is complicated by the fact that we do not know any ideas only concepts and those

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confusedly and indistinctly. Nonetheless, over time, we can get closer to ideas and thus to an

understanding of the physical universe.

Nominalism

Leibniz does not regard ideas as things that exist. Nonetheless, he sees a certain necessity to

them. He regards ideas as being able to be instantiated in the physical universe and, indeed, as

the only things that can be instantiated in phenomena and processes in the physical universe.

Richard Brown writes, “To Leibniz nothing exists independently of individuals. Common

properties shared by individuals do not actually exist in re; they are purely creations of the

mind.”459 Once an idea has been instantiated, the instance exists in re, but the idea does not

exist in re.

Having regard to the standard definition of Nominalism,460 Leibniz denies both the existence

of universals and also of abstract objects.

For Leibniz, not all universals are abstract objects. An abstract object is a mental artifice,

which is either a concept or an idea. A concept is a confused intellectual creation which might

be useful notwithstanding its confusedness. An idea is a refined concept, that is consistent

with every other idea. A concept that is not an idea cannot be instantiated in the physical

universe but an idea must instantiate at some point.

“Universals” like whiteness (the example at the Stanford Encyclopedia of Philosophy), or

strength or humanity (the examples from the less formal and more popular Wikipedia), are

nothing but a concept laced with opinion derived from sense perception and useful for day-to-

day conversation. It is a particularly vague kind of concept, and a kind of concept which we –

at least in Western culture at the time of writing – are not motivated to evolve upwards into an

idea because it a serves a role in its vague form. Other kinds of concepts, like mathematical

and metaphysical ones, should be developed into ideas so that they may be of use – or of

greater use – in physics and in helping to understand the universe as a whole. The evolution of

Euclidean geometry to non-Euclidean geometry is an example.

Thus, we have the paradoxical position that ideas are discoverable a priori, but anything

found a priori does not exist and is only a thought with some status or other, whether pure

idea, pure concept or something between. At the same time, a priori discoveries are useful in

understanding that which has been instantiated in the universe because the universe adheres to

the concept of the Best, and we know that God uses ideas to design and choose the Best for

the design and unfolding of the universe. Hence, a priorism – particularly with a Nominalist

foundation – can only make sense when we are consciously attempting to retrace God’s

thoughts. Were one not Nominalist, a priorism could conceivably be used to directly discover

the universe. As a Nominalist, however, thoughts are useful in understanding the physical 459 Brown, R. C. Leibniz, unpublished, Chapter 4 “A Young Central European Polymath Between the Scholastics

and the Moderns” p.33 460 Rodriguez-Pereyra, G. “Nominalism in Metaphysics” 2008 revised 2001, in Stanford Encyclopedia of

Philosophy http://plato.stanford.edu/entries/nominalism-metaphysics/ accessed 21 Feb 2012, with which the

popular source Wikipedia agrees at http://en.wikipedia.org/wiki/Nominalism accessed 20 April 2011

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universe to the extent that they are similar to – or help us understand – the modus operandi of

the Creator.

Interdependence of ideas

If you grasp one idea, you grasp them all. But you cannot grasp any one idea without grasping

them all. We explain why.

1. We start with a question: Is to truly understand an idea to grasp all of its consequences,

which are – by the principle of plenitude – all of its manifestations in the physical

universe? The answer is yes, both by Leibniz’s “Art of Reasoning Well” and by

Leibniz’s conclusion on the qualities of the thoroughness with which God perceives

and understands.

2. No idea can be brought to bear in phenomena independently of any other idea because

the entire universe is needed for each and everything in it. For example, the rest of the

universe would make no sense if Mars were removed from it, and Mars is a necessary

consequence of everything in the universe other than Mars as well as of Mars itself.

The same argument holds when we replace “Mars” with anything else in the universe

including “humanity”, “John Smith” or any individual human being, and any grain of

sand. There is thus a connection between any two ideas, and therefore between all

ideas. It might be easiest for human minds to find that connection using the chain of

dependencies that can be found in the physical universe rather than relying on the

distinctness of perceptions to do the same with ideas in the mind. Since there is a

perfect harmony between soul and body, what we can say about necessary

dependencies in the domain of efficient causes (the physical universe) we can

immediately say about the domain of final causes (the immaterial universe). (See the

above heading “Immaterial realm is in harmony with material realm”.)

3. Thus, no idea can be fully understood independently of any other idea. This means

that we cannot fully grasp the truth or the consequences of the angle sum of a triangle

unless we perceive all ideas at once, which no human will ever do. This has enormous

consequences even for “closed systems” of ideas like Euclidean geometry. In effect,

we cannot fully understand the necessity or consequences of any part of Euclid’s

system without understanding all ideas. Now that some kinds of non-Euclidean

geometry are understood, we understand that Euclidean geometry is just a particular

limiting case of a broader geometry. We know that Euclidean geometry could not

manifest in the physical universe expect in extreme circumstances.

4. Thus, to understand any idea in the domain of ideas is to understand all ideas – i.e.

everything – in that domain. To have such understanding, in turn, is to understand

every possible manifestation of those ideas in physical form.

5. Since every possible manifestation of those ideas has been realised in physical form,

according to the principle of plenitude, and in the most minimal way, according to the

principle of sufficient reason, it thus follows that to understand ideas is to understand

the entire physical universe, and vice-versa.

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6. One cannot understand the physical universe without necessarily and automatically

having grasped the ideas which govern it, or which it accords to because for the

universe to so accord makes it the best possible.461

7. The conclusion is that understanding any idea is to understand the entire universe.462

The conclusion is consistent with Leibniz’s view that the entire universe is contained in a

single grain of sand. This is just a physical analogy of the metaphysical fact that every monad

perceives every other monad albeit with varying degrees of distinctness.

The corollary of the above conclusion is that humans do not understand any single idea and

never will. Even now, for example, all the consequences of the Euclidean concept that the

angle sum of a triangle is 180° are not known. Of course, that concept is not even an idea

because it is not consistent with every other idea. It acted as an hypothesis for many centuries,

but ultimately was done away with.

Do we know any idea? We know some such as “God is creative” though few humans ever to

have lived would know the meaning that would need to be ascribed to “God” and to

“creative” in order for that statement to be correct, i.e. for it to be an idea and so consistent

with every other idea. Similarly with the statement “God is good”.

The large class of statements we think we know, the mathematicals, are not as evident as they

first seem to be. For example, the statement A B A B requires qualification to avoid

nonsense, such as when A and B . The statement A A A does not hold in linear

logic in which propositions act like resources.

Simple monads and compound monads

Another word for monads is “unities”, and the words are similarly connected to the idea of an

indivisible unit or a whole or a One. Leibniz explains that monas means unity or one, in his

preface to Monadology.463 Physical bodies or objects as we experience them, on the other

hand, are multitudes/compound monads which can be destroyed through dissolution of their

units. By inference, this answers the question of how compound monads are formed. Monads

aggregate to form a compound as part of the divine choices made for the best in the way the

universe unfolds from the infinity of possibilities in conformity with ideals.

461 The “least time” principle of the refraction of light is an example. This “idea” makes sense when we embed

the concept of light in the physical world. Theoretically, we may have been able to derive it a priori, but it is

unlikely that it ever would have been. Nonetheless, the principle is a consequence of the Best-ness of the

universe. 462 The Corpus Hermeticum implies this, because it posits the concept of “a nature that enables a thing to come

to be” and “a nature that prevents a thing from ever existing”. (This also relates to the concept of “the good”

as the final cause in Plato’s Timaeus and Phaedo.) This is a unifying concept across all things in the universe

and all things that do not exist. If we understand why one thing exists, then we will understand why every

thing exists. If there is something missing in our understanding of one thing, then – because the existence of

each thing is based on a foundation common to all things – our understanding of everything else must also be

incomplete. Corpus Hermeticum II, §§12-13 in Copenhaver, B.P. (trans. and ed.) Hermetica Cambridge

University Press 1992, p.11 463 “The principles of nature and of grace based upon reason” 1714 Loemker p.636, §1

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Leibniz’s concept of the pre-established harmony ties the incorporeal part of the universe

where souls “reside” with the corporeal. A single soul monad in the incorporeal domain can

control many monads in the corporeal domain at once. The example of the human body was

just what I thought was an easy way of showing how a single soul monad can neatly be tied to

a multiplicity of monads in the corporeal domain – which I am calling “body monads” for

convenience – through the pre-established harmony.

The soul monad is simple in that it is indivisible, has independent perceptions and exists in

incorporeality. Any given soul monad is tied to a body monad through the pre-established

harmony.464 A single soul monad in the incorporeal domain can control many monads in the

corporeal domain at once. We will use the example of the human body to demonstrate how a

single soul monad can be tied to a multiplicity of monads in the corporeal domain through the

pre-established harmony. Since Leibniz writes that every soul monad is tied to a body monad

through the pre-established harmony, it must be said that, for all intents and purposes, a soul

monad only consciously acts on compound monads. For example, a human mind which

Leibniz largely conflates with the soul can move its little finger or their whole body. However,

even the little finger comprises trillions of independent body monads. The soul does not have

any business with each of those trillions of individual body monads but only with the whole

that we call “the finger”. We cannot rule out the possibility that a soul monad has a pre-

established harmonic individually with each of the trillions of independent body monads that

make up the little finger compound monad.

Thus, we make Leibniz’s framework more precise by adding that the soul monad is tied to a

definable boundary compound body monad through the pre-established harmony. For a

person, that boundary compound body monad is commonly called the “human body”. This is

the largest compound monad with which the soul has a pre-established harmony.

Alternatively, we could say that the human body is the largest compound monad over which

the human soul (which is itself a monad) has direct “control” though that control is really just

a manifestation of the pre-established harmony. The soul monad is also tied to a multiplicity

of smaller compound body monads that comprise the boundary compound monad. For

example, the left leg forms a compound monad that is part of the boundary monad. Though

Leibniz did not extend the idea much further, we can say that that the boundary of control can

be extended indefinitely by the building of machines and other, wider forms of influence of

humans over the physical universe. However, when humans influence vast areas through

projects such as dam-building, railway construction, farming and forestation, it is not only

human souls that are at work. Rather, the decisions of human souls are influencing processes

that will function in a new or altered way – at least for a time – even without ongoing human

intervention.

Another extension we can make is that soul monads usually work as compounds too. In the

case of people, most people take their perception and appetitions from others or from their

perception of the group’s perception and appetitions. Still, even an individual soul monad’s

perception of the group is its own. Each of two monads in a mob who are each blindly

following their own perception of the mob has a radically different perception of the mob. The

464 Monadology, p.262 §78

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difference between those two may not appear to be very great judging from the

actions/phenomena that arise from those monads’ “membership” of the mob.

Figure 5: How a soul monad typically communicates with another

Figure 6: More general schematic of soul monads and body monads

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We now return to elucidating on Leibniz’s conception of monads. As Figure 5 indicates, there

is no direct communication between the two body monads except via ideals manifested in the

laws of physics. Figure 5 also helps conceptualise how a soul monad can be tied to a set of

compound monads whose simple monad constituents are all members of some fixed set.

Passive vs active, or body vs soul

The theory of pre-established harmony does not imply that the body is a ship without captain

or crew which somehow reaches its destination regardless (as Bayle complained).465 This is

because God mediates between the two to make it work. The mediation is in conformity with

“pre-established harmony” which is like the law of gravity. God would never decide to act

against this law any more than he would suspend gravity for a day, as there would not be a

sufficient reason to do so and it would diminish the harmony and grandeur of the universe.

It is significant that Leibniz notes that everything is a monad and that monads are substance

which would cease to exist without ongoing perception and activity. In other writings, Leibniz

agreed with Aristotle that there are whorls in every part of matter, which never cease in their

motion. These two positions are consistent.466

If an imperfect monad can only be acted upon, i.e. can only suffer,467 how can we distinguish

an extremely imperfect and thus passive created monad from an asteroid which is a physical

body and thus a compound monad? The difference is two-fold. First, the monad albeit

imperfect is eternal whereas the asteroid is not. Second, the monad has some perfection

however minute whereas the asteroid (qua asteroid, i.e. rock) is entirely passive albeit that it

comprises relatively passive monads with unceasing internal activity.

There are two extreme kinds of monad: body and soul. In fact, monads are on a continuum

between these extremes. The former kind operates in the domain of efficient causes or

physics, which is nothing but metaphysical principles and mathematical rules – i.e. ideals.

Thus, body monads are passively subject to those “laws of nature”. The latter kind is driven

by perceptions and appetite, which do not always correspond since the passage “from mind to

heart is so long.”468 Thus, soul monads can make decisions. These are known as final causes.

Body monads are controlled by the laws of physics and by the decisions of corresponding

soul monads. The clearer and more distinct the perceptions of a soul monad, the more power

it has to affect other monads. (On the ground of ability to affect other monads, God has

465 1705, Loemker pp.586-7 466 Also consistent is Hermes Trismegistus. “There is nothing that is not a product of the cosmic fecundity. In

moving, it makes all things live, and it is at once the location and craftsman of life.” Corpus Hermeticum IX

§6 Copenhaver, p.28. Also see Corpus Hermeticum IX §8 in Copenhaver, p.29. In Corpus Hermeticum V §5,

Trismegistus writes that motion is indispensable to – indeed, part of – the fecundity of the cosmos and “This

is the order of the cosmos, and this is the cosmos of order” in Copenhaver p.19. 467 Monadology, p.245 §49 468 “Hence it comes that our soul has so many means of resisting the truth which it knows, and that the passage

from mind to heart is so long. Especially is this so when the understanding to a great extent proceeds only by

faint thoughts, which have only slight power to affect, as I have explained elsewhere. Thus the connexion

between judgement and will is not so necessary as one might think.” Theodicy, p.311 §314

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infinite power.) Leibniz’s theory of intention subsists in the power and tendency of monads to

affect other monads which will not be investigated further in this thesis.469

The theory of pre-established harmony is a harmony between efficient and final causes.

Accordingly, Leibniz says that neither efficient nor final causes are adequate without the

other.470 This is Leibniz’s resolution to the problem of dualism and his answer to Descartes’

occasionalism.471

Nothing can be found in a simple substance or created monad but perceptions and their

changes.472 However, the ability to perceive does not imply consciousness.473 So not all

created monads are conscious.

Actions of monads

Latta writes that a created thing can act outwardly to the degree of its perfection, and can but

be acted upon to the degree of its imperfections.474 No monad can act outside of itself.475

However, it would appear for all intents and purposes that it can act:

(a) On the body via pre-established harmony, albeit that that harmony was put there or

implemented by God.

(b) On other monads via the intermediation of God albeit this is always in conformity

with ideals.

At a precise technical level, however, Latta is correct.

A created monad, due to confused understanding (i.e. “perceptions”), can cause its

corresponding body to ingest beer so causing further confusion and leading to a nobbling of

the mind/soul monad’s ability to control the body. That is, the pre-established harmony

reduces the refinement in the physical motion of the body in line with the confusion in the

perception of the soul monad which the alcohol somehow caused. In short, pre-established

harmony works both ways. The alcohol also nobbles the ability to reason and remember.

Platonically, referring to Meno, reasoning and remembering are the same thing noting that the

memory activated in Meno is of thoughts that have always been with the soul, i.e. since the

beginning of time, albeit in indistinct form. Thus, the physical action of the chemical of

alcohol on the brain is affecting the perceptions of the created monad or soul.476

469 C.f. Hill, J.C.R. Leibniz’s metaphysics of intentionality PhD 2008, National University of Singapore 470 Loemker, p.588 middle of first paragraph 471 Robinson, H. “Dualism” 2003 revised 2011, in Stanford Encyclopedia of Philosophy. Accessed at

http://plato.stanford.edu/entries/dualism/ 21 Feb 2012 472 Monadology, p.228 §17 473 Loemker, p.588 7th last line 474 Monadology, p.245 §49 475 Monadology, p.245 footnote 79 476 Without referring to monads, Friedrich Schiller addressed the impact of the body on the soul and vice-versa in

“On the connection between the animal and spiritual nature in Man”, Letter V of Schiller’s Philosophical

Letters Tapio Riikonen, T. and David Widger, D. (eds) accessed at http://www.gutenberg.org/files/6799/6799-

h/6799-h.htm on 1 Jan 2011

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Immaterial realm is in harmony with material realm

It is not just pairs of monads, simple and/or compound, that are in harmony with one another.

The entire realm of final causes (souls) is in harmony with that of efficient causes (bodies).477

This does not mean that they move in lockstep and are copies of one another. However, it

must mean that they are derivable each from the other because harmony implies that the

“connection of ideas” is indubitable when properly worked out.478

Life

Souls are themselves vital principles with perception and appetite. The appetite means that

they must also have intention provided they are not passive.479 If they have memory, then they

are intelligent to varying degrees.480

Substantial forms include rational souls, but not in an organic body such as a stone. Further,

there is no part of matter that does not include an infinity of organic animated bodies. Thus,

even the stone does. However, there is matter which nevertheless is not animated in spite of

what is in it. So a stone is not animated though it has in it an infinity of animated bodies. A

pond is not animated even though it has fish in it.

Q&A

In order to clarify some of the concepts raised, we segue to a question and answer format with

these five bullet points:

What are such non-animated bodies? Compound monads

Are they merely ideas? Yes. Are they actual but non-permanent and without memory. No

Since a thing without motion – though its parts have motion – does not exist, then such

non-animated bodies do not exist. Correct

Does this include all compound monads? Yes

If they are ideas, then are they not provably and permanently true? Yes, but they are

implied by the entirety of the rest of the universe. When the rest of the universe changes,

including their constituent monads, they are no longer implied and thus are not necessary.

A vital principle is a substantial form. Only animated matter, animated bodies and conscious

monads are substantial forms. Thus, a vital principle is “life” and not all monads have life.

Vital principles are not eternal for a living thing may die.481

477 Monadology, p.263 §79 478 Loemker, p.638 §5 479 C.f. Hill, J.C.R. Leibniz’s metaphysics of intentionality PhD 2008, National University of Singapore 480 1705, Loemker p.586 and Monadology pp.244-5 §48 481 To Hermes Trismegistus, death is merely dissolution. Corpus Hermeticum VIII §4 in Copenhaver pp.25-26,

Corpus Hermeticum XII §16 in Copenhaver pp.46-47

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Sentiment is perception accompanied by memory, i.e. there is an echo of the perception for

some time afterwards. A living being with sentiments is an animal, its monad is a soul. When

the soul has reason, it is a spirit.

Since everything comprises monads and monads are with perception and thus animated, there

is “life” everywhere, even in the coldest asteroid.482 For Leibniz, every cubic millimetre of the

universe is packed full of substance; that is, the universe is a plenum.483 For Leibniz, God

would not create a universe in which there was any empty space or in which two things were

alike because either would amount to redundancy, violating the principle of sufficient reason.

Since the asteroid qua an asteroid is inanimate, it is only an idea – i.e. it does not really exist.

This is even though the compound monad must conform to metaphysical principles and

mathematical rules, as must its behaviour and that of its constituent created monads. This is

consistent with the consequence of Leibniz’s theory that only God and simple substances

exist. Leibniz affirms this when he writes, “Sensible things, however, and composite things in

general, or the substantiated things, so to speak, are in flux and become rather than exist.”484

For example, the asteroid is undergoing a constant exchange of simple monads with its

environment. As far as biological organisms on earth are concerned, such exchange with the

environment and ingested nutrients is well-established and confirmed by experiment. Leibniz

is saying that this is true of all composite monads.

The Hermetic monad

In a discourse of Hermes to Tat, Hermes explained that God sent down to the physical

universe a great mixing bowl which was “Mind”, inviting all human hearts to immerse

themselves in it. Those who did, and who do, participate in knowledge and become

“perfect people because they received mind”.485 The mixing bowl or “Mind” is the

monad of Hermes. Hermes says that the monad is in all things as a root and beginning,

presumably because all things have mind to some degree however small. Nicolaus of

Cusa’s conception of mind is similar to that of Hermes, for tells a story similar to

Hermes’ mixing bowl whence all souls may sup of Mind and so acquire their own

mind.486 482 Restated in Leibniz’s 1714 essay at Loemker p.636 §1 last two lines, and p.637 §4 first two lines. 483 For Hermes Trismegistus, there is nothing which is empty. Even hollow containers are “full of air and spirit”.

Hermes finds it almost blasphemous to imply that any of the things that are, is empty. Rather, all that is is full

of substance. Corpus Hermeticum II §§10-11 in Copenhaver, pp.10-11 484 Loemker, p.592 (Letter to Hansch, July 25, 1707) 485 Corpus Hermeticum IV §4 in Copenhaver, pp.15-16 486 For, to Cusa, when treating of an individual mind, he says that the mind is the first and the most simple image

of the divine enfolding. The mind comprises the power of understanding, reasoning, imaging and sensing as

its elements, meaning these various powers can be combined in multifarious ways. When the Philosopher

asks the Layman where the mind gets these powers, the Layman answers, “From unity,” which would seem

to correspond to Hermes’ mixing bowl which was sent down by God. Miller, C.L. (trans. and intro.) Nicolaus

of Cusa Idiota de Mente Abaris Books, New York 1979, pp.51, 83. Credit goes to Miller for tying together

p.51 and p.83 and putting them neatly side-by-side in his introduction. The connection we have drawn and

not taken from Miller is that between Cusa’s conception of mind as coming “from unity” and the mixing

bowl of Hermes.

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Things without any mind, in Leibnizian terms, would be pure body and for Leibniz this is

extremely rare and does not get much elucidation from Leibniz. For Leibniz, each thing that is

real – except God – is a monad whether or not it has developed an intellectual faculty worthy

of the name “mind” (small “m”).

Since souls are what the universe is made of, and since humans have incorporeal souls

(which, popularly, is the only kind of soul), let us examine Leibniz’s theory of death.

What survives death?

Since souls are eternal, what happens after that which we call “death”? Leibniz addressed

Pythagoras’ conception of transmigration of souls487 and wrote that his own theory implies

even more. It is not only the soul that is indestructible.488 Not only does the animal’s soul

subsist after death but the entire animal does. So there is no metempsychosis but there is

metamorphosis.489 This is clarified when Leibniz explains that an animal might change its

“organic slough” as its “machine may often perish in part”.490

The personality of beasts is not preserved on death, though the personality of humans is

preserved. While beasts’ souls are merely indestructible, human souls are immortal. In the

case of humans, “not only the soul but also the personality subsists. In saying that the soul of

man is immortal one implies the subsistence of what makes the identity of the person,

something which retains its moral qualities, conserving the consciousness, or the reflective

inward feeling, of what it is”. However, “this conservation of personality does not occur in the

souls of beasts: that is why I prefer to say that they are imperishable rather than to call them

immortal.” (emphasis in original)491

Human souls differ from souls of beasts

Leibniz is emphatic that animals have souls too, in opposition to the Cartesians. However, he

is also emphatic that the intelligence of humans is such that humans must and should rule over

the beasts.492 Descartes argued that beasts are mere machines, and Bayle took Descartes’ side

against Leibniz.493 Presumably, no soul monad is a mere machine, though soul monads –

especially those which correspond to passive matter – may often approximate mere

mechanism. Indeed, from the superficial perspective of textbook physics, this is what makes

the behaviour of inanimate matter amenable to human study and human control.

487 Loemker p.589 488 Monadology, p.262 §77 489 1714, Loemker p.638 §6 last paragraph and p.637 §4 490 Monadology, p.262 §77 491 Theodicy, §89 p.171 492 Langley, A.G. (ed.) New Essays on Human Understanding, 1949, p.97 493 Theodicy, pp.40-41

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Leibniz muses, “It is certain that God sets greater store by a man than a lion; nevertheless it

can hardly be said with certainty that God prefers a single man in all respects to the whole of

lion-kind.”494 Later, he says the maxim “that all is made solely for man” is “old and somewhat

discredited”.495 Far from making Leibniz an environmentalist or animal-lover, we can really

only conclude that Leibniz is opposed to gratuitous mistreatment of animals. Leibniz says that

punishing and even killing animals would be justified if it effectively prevented beasts from

causing disorder or other harm in human society.496,497

Animals have rational souls, as do humans. However, human souls are “raised to the rank of

reason and to the prerogative of minds”. Minds are “images of the Deity” whereas ordinary

souls are not.498,499

Monads are the same as one another

All that exists must be interrelated, and therefore everything must express the same nature but

in a different way. All minds have intercourse with each other and express the same nature.500

Consistent with this is that every monad contains within it complete information on every

other monad and, thus, complete information on the entire universe. However, such

perceptions are confused and indistinct.501 Because all monads are on this equal footing,

Leibniz says that all of history, both sacred and profane, is confirmed.502 (We also discern

from this that no monad – much less a soul monad – is a mere machine but can potentially

manifest complex behaviour. The internal state of such entities would be orders of magnitude

greater in richness than their overt behaviour may appear to be, though not prohibitive of

being understood.)

494 Theodicy, §118 p.188 495 Theodicy §118, p.189 496 Theodicy §70, p.160 497 Hermes wrote that all creatures should multiply, though of course only intelligent creatures would be able to

comprehend the diktat: “[G]od immediately spoke a holy speech: ‘Increase and increasing and multiply in

multitude, all you creatures and craftworks.’” Corpus Hermeticum I §18 in Copenhaver, p.4. Of course, in

Genesis I:28, God directed God to, “Be fruitful and multiply.” 498 Monadology, pp.264-265 §§82-83 499 Hermes wrote, “Nothing is more godlike than mind, nothing more active nor more capable of uniting humans

to the gods and gods to humans. … Blessed is the soul completely full of mind, wretched the soul completely

empty of it.” (Corpus Hermeticum X §23 in Copenhaver, p.35) This and the mixing bowl or monadic “Mind”

of Hermes (Corpus Hermeticum IV §4 in Copenhaver, pp.15-16) suggest that Hermes regards soul’s embrace

of mind as a choice for humans in the degree to which a human mind imbibes of Mind. Hermes does not

suggest that animal souls can choose to embrace Mind more, in order to be elevated to the form or state of

humans. However, Hermes does say that the greater the degree to which a human soul embraces Mind, the

closer they reach to God (though Hermes uses a lower case “g” and sometimes refers to “gods”). Whether a

human soul embraces body – and its pleasures – or Mind is a choice that it is within the power of humans to

make. This is consistent with Leibniz’s view of a continuum of activity and passivity between human minds.

The more active have to a greater degree embraced Mind, in the Hermetic sense. 500 Loemker, p.365 14th last to 10th last lines of 2nd-last paragraph 501 Loemker p.590 last 3 lines of last paragraph, and Monadology p.248 §56 502 “On the method of distinguishing real from imaginary phenomena” Loemker, p. 365

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Since simple monads’ perceptions are “indeterminate”, i.e. non-ideal, the choice of the best

possible universe is a choice leading to superior guidance of our and other simple monads’

internal perceptions and so affect their “appetitions” and thence their decisions. Indeed, even

galactic events are impinging on the perceptions of humanity, and so are affecting our

decisions and behaviour.503,504

Conclusion

Leibniz formulated a coherent system which embraces material reality, immaterial reality,

God, ideas and thought. There are many exciting directions to take from here, not least the

one which Leibniz prescribed: creating a Universal Characteristic.

The Leibnizian conception of the physical universe as outlined in this chapter shows Leibniz

to be Nominalist. However, Leibnizian Nominalism is qualified by the necessity of the Best,

since only the best may ever manifest in the physical universe. Things can be the Best only

when they correspond to ideas, though we do not know whether correspondence with ideas is

sufficient – it probably is. Thus, we can increase our understanding of the physical universe

by studying ideas because, of all possible thoughts and concepts, only ideas can be

instantiated in the physical universe. Since ideas have structure and clarity, they can often be

given mathematical form and are subject to calculation. This is why mathematics is

indispensable to physics, and why mathematics sometimes precedes physics.

Perhaps the most important idea of all is that of the Best, since it subsumes all other ideas.

Arguably, Leibniz’s “the Best” is what Plato referred to in The Republic as “the good”. An

idea is only instantiated at a particular point in any series of events if it is consistent with the

Best. It is the need to understand “the Best” which often places metaphysics, aesthetics and

art, and theology prior to mathematics and physics. The first three situate, contextualise and

bound how close human thought can approach “the Best” in their endeavours through

mathematics and physics.

503 Loemker, p.640 §13, 2nd sentence, 2nd paragraph 504 A possible example of galactic events directly impinging on humanity is given by the paper on the effect of

our solar systems passage through a spiral arm of the Milky Way on earthly climate. See Shaviv, N.J.

“Cosmic Ray Diffusion from the Galactic Spiral Arms, Iron Meteorites, and a possible climatic connection?”

Physical Review Letters 2002 Vol. 89 Issue 5

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Chapter 8: The ongoing role of thought and the ongoing creation of the Best

Introduction

The Best is made more complicated – or richer, or more harmonious and beautiful – by the

proactive and wilful role played by thought in the running or “unfolding” of the physical

universe. These are the thoughts of souls – in particular, human souls and other souls equally

capable as human souls though we presently do not have direct evidence of any of the latter –

which are in symbiosis with the appetitions of, or the choices made by, souls. Choices are also

made by God in the interaction between souls and the physical universe. Physics cannot be

complete without subsuming the role of these thoughts, appetitions and choices. A calculus or

some kind of mathematics is needed to help our human minds cope with it in a structured

way. These thoughts and choices are indispensable to the “onward and upward” unfolding of

the universe in the Best possible way. Without these thoughts, appetitions and choices, the

universe would be inferior to what it is, it would certainly not be the Best, and it – for reasons

not yet understood by this writer – might not even be possible.

There is an apparent contradiction in the fact that God makes choices from moment-to-

moment in the unfolding of the universe, and the fact that Leibniz held that a universe that

requires intervention by God must be imperfect. This contradiction vanishes when we

understand that the universe only appears to be running or operating from moment-to-

moment. It is actually being re-created anew from moment-to-moment per the perceptions or

thoughts of soul monads which, to varying degrees, are changing in tandem with the

unfolding of the physical universe. The relationship involved in that tandem-ness requires

further study, and it essentially is nothing but Leibniz’s concept of the pre-established

harmony.

In this chapter, these matters are addressed: the choices God makes, the ongoing creation of

the universe, the role of the thoughts of souls, the role of free will and the necessity of

including intellectual intent in physics.

Choices God makes, continuously

While the physical universe functions without divine intervention, a contradiction in Leibniz

is that the Monadology has God making choices continuously.505 The “choices” are “made” as

a result of the universe and the intentionality built into its design. Thus, the choices are not

directly of God but are of the universe. The universe functions almost as an intelligent entity

505 The same apparent contradiction is in Hermes when he says, “sensation and understanding enter from outside

… but the cosmos got them once and for all when it came to be, and, having got them, it keeps them by god’s

agency.” (Corpus Hermeticum IX §8 in Copenhaver p.29) How can it be said that the cosmos has them once

and for all when god’s agency is needed to keep them? Further, as we know from Hermes, once something is,

it can never not be. We can only suppose that the contradiction is to be resolved as with Leibniz. The

“agency” by which these things continue to exist is only indirectly of God; directly, it is of the cosmos which

was fathered by God, to use Hermes’ words.

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or system that makes choices continuously. We now explain Leibniz’s theory using his

terminology.

First kind of choice: God mediates between monads

No monad can affect another of its own accord. This is natural since monads are all self-

sufficient. However, monads act on one another through the mediation of God. We remind the

reader that we are forced to read Leibniz as meaning “through the intentionality of the

universe which God created”. Such mediation is only ever in accord with ideals.506 Thus,

there is not really a “choice” for God, because he always finds and chooses the best

possibility though he has the power not to so choose. Whence, we understand why Leibniz

says that (the functioning of?) the entire universe relies on “God” for its existence each and

every moment.

Grace cannot be understood by reason but only by revelation. We leave this to one side since

the natural workings of the physical universe are untouched by grace, as they are governed by

metaphysical principles and mathematical rules. For God to arbitrarily modify these would be

an imperfection in the order of things.507 Thus, the reliance on God’s mediation is not through

grace as such, for God would not choose to act in any way other than the best and that, in

turn, is in accord with ideals.508

Perhaps the pre-established harmony is a subclass of the interaction between monads in

conformity with ideals through the mediation of God. Since it adheres to ideals, it is in that

sense pre-established. However, it is not pre-established in the sense that the perceptions of

the soul are indistinct and so the choices unpredictable or, at least, non-ideal. Or, to God, they

are largely predictable because he knows the internal perceptions, and their changes, of simple

substances or created monads.509

Nicolas Malebranche was a philosopher who was a contemporary of Leibniz. Malebranche

lived in Paris from 1638 to 1715. Malebranche concluded that “there is only one true cause

because there is only one true God; …the nature or power of each thing is nothing but the will

of God; … all natural causes are not true causes but only occasional causes”.510 This is now

known as occasionalism. Leibniz’s thesis that God mediates between monads seems to verge

on occasionalism, it has very different conclusions. While occasionalism denies any causation

aside from God, monads by contrast determine their own internal states. Thence, interactions

between monads are affected. That is, the internal states of monads are independently driving

unfolding order of the universe. Leibniz’s doctrine appears similar to occasionalism, but it

leads to a conclusion contrary to occasionalism.

506 Monadology, p.246 §51 507 1702, Loemker p.556 final paragraph 508 Loemker p.639 §10 509 Monadology pp.228-9 §17 510 Robinet, A. (ed.) Malebranche, N. Oeuvres complètes de Malebranche Vrin Paris 1958–84, Vol. II, p.312.

Quote in Lennon, T.M. and Olscamp, P.J. (trans.) Malebranche, N. The Search for Truth and Elucidations of

the Search for Truth Cambridge University Press 1997

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Second kind of choice: God chooses the best possible from what is possible

There is an infinite number of possible universes511 all in accord with ideals or they would not

be possible. God chooses the best of all that are possible.512 Ideas are as they are, and ideas

cannot be mutually contradictory or some of them would not be ideas. Therefore, the

difference between possible universes can only be our and all monads’ perceptions. Another

way of considering this is to “distinguish metaphysical necessity from moral necessity”.513

Furthermore, God does not act purely “according to mathematical laws, following an absolute

necessity”.514

In short, “nature leads to grace and grace perfects nature by using it.” Here, “nature” means

metaphysical principles and mathematical rules represented by the laws of physics.515 This

use of the word “grace” does not mean “grace” in the usual sense of miraculous divine

intervention, for a propulsion towards the best possible outcome is subject to an ideal or rule.

Can a calculus of such “best outcomes” be produced? However, we pre-empt ourselves for we

need a calculus of metaphysical principles first. Indeed, we are a long way even from an

overarching calculus of mathematical rules. However, it might make sense to start on all three

projects simultaneously as they might assist each other.

God must be making a choice continuously based on sufficient reasons for the best of all

possibilities which God perceives in his mind all at once. This is not Zeusian arbitrariness in

playing with the universe and humans. If we had the all-encompassing perceptive ability of

God, we would know what he will choose.516 Leibniz suspends judgement on the extent of the

role of grace in God’s making the choices,517 though we do know that Leibniz denied the

necessity of grace to this universe being the best possible one.

Were it not for this selection undertaken by God, the principle of plenitude would imply that

the domain of ideas bears a one-to-one correspondence with the physical universe. However,

this cannot be true because there is an infinite number of possible universes which conform to

metaphysical principles and mathematical rules, when in fact only one universe exists.518

511 Monadology, p.247 §53 512 Also, “The dominion of his will relates only to the exercise of his power, he gives effect outside himself only

to that which he wills, and he leaves all the rest in the state of mere possibility.” Theodicy, p.243 §183. Also

see Loemker p.640 §12. 513 Theodicy, p.313 §310 514 Theodicy, p.399 §8 515 Loemker p.640 2nd half §15 which is related to last 4 lines of Loemker p.639 §9 516 Monadology p.248 §55 517 Loemker p.590, end of first paragraph 518 This indicates that Leibniz has much more fine-grained criteria than Hermes Trismegistus who says, to

paraphrase, what is will always be and what is not never will. (Corpus Hermeticum II §13 in Copenhaver

p.11) Or has Hermes assumed the best possible world doctrine in referring to that which has it in its nature to

be? Even if he has, Leibniz’s view is more refined because Leibniz considers the unfolding of events so that

what may be now is different from what may be after, say, the earth has completed its current orbit around the

sun. Hermes regards being as a timeless or eternal matter, whereas Leibniz allows for change and trajectories

of events.

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Unanswered question re first kind of choice

When does God need to mediate or communicate between soul monads, albeit he always does

so in conformity with ideals? Alternatively, when do two soul monads ever communicate or

impinge upon each other except via the laws of physics via corresponding body monads?

Leibniz does not provide an example. It is unlikely that God ever does. However, Leibniz

probably does not wish to contradict the Bible by excluding the possibility of miracles. Most

likely, Leibniz believes that there is a scientific explanation for what apparently are

miracles.519

Consideration re first kind of choice: God’s choices vs intelligent monads’ choices

Ideals matter in the outcome of interactions between monads. They also happen to produce

maximum harmony and beauty, and the best possible outcome. They govern choices by God

“on behalf of” passive substance (e.g. planets) in order that our perception may grasp this

harmony and be improved by it. God makes such choices because they please him.520

So, in any case, God is extremely active (infinitely so) in producing “the most beautiful

combination of justice and goodness which could be wished”.521 It is through this continuous

selection process that God creates a repayment of good from evil plus interest.

Clear and distinct perceptions in a monad are different from appetition. Leibniz says little

about what determines appetite. Presumably, clarity on certain ideals (such as justice and

goodness) will generally create concomitant appetite, whereas clarity on other ideals (such as

plenitude) without clarity on, say, justice and goodness might lead to evil appetite. However,

this is not necessarily the case. The passage “from mind to heart” is long.522 Such monads

might have power for good or evil in the universe, respectively, depending on the combination

of ideals and conceptions perceived and the degree of clarity with which they are understood

by the monad. Monads capable of any of these were made by God in his image. Leibniz also

calls such monads “spirits”.523 “The mind is not a part but an image of divinity, a being which

represents the universe, a citizen of the divine kingdom.”524

Leibniz draws parallels and distinctions between God’s knowledge and a created monad’s

perceptions, and between God’s will and a created monad’s appetite.525 The latter qualities (of

519 Leibniz did believe that it is scientifically possible for water to turn into wine, and for the body of Christ to be

in several places simultaneously. He wrote metaphysical explanations as to how these phenomena are

possible, which we will not address in this thesis. 520 Loemker p.575, 16th line from the bottom 521 1705, Loemker p.590 522 “Hence it comes that our soul has so many means of resisting the truth which it knows, and that the passage

from mind to heart is so long. Especially is this so when the understanding to a great extent proceeds only by

faint thoughts, which have only slight power to affect, as I have explained elsewhere. Thus the connexion

between judgement and will is not so necessary as one might think.” Theodicy, p.311 §314 523 1705, Loemker p.590; Loemker p.637 §4 first paragraph; Loemker p.640 §14; Loemker p.640 §15 first half 524 Loemker, p.595 (Letter to Hansch, July 25, 1707) 525 Monadology, p.245 §48

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the monad) are only imitations of the former qualities (those of God), with a quality

corresponding to the degree of perfection of the monad.

Question re second kind of choice

What is an example of where there might be a choice, both options in conformity with the

laws of physics, one tending to the better and the other to the worse – where God of course

chooses the former?

One is reminded of the postmodern “chance event” films where the falling of a cigarette butt

in a particular square centimetre of floor triggers a course of events which changes a person’s

day or life. But even in this case there is no place for a choice to be made by God, for the

coordinates of the location where the cigarette butt falls is determined by the laws of physics

and since people have free will God cannot intervene in their perceptions, decisions or

reactions.

The overriding contradiction is that Leibniz said in several places that a universe which

required intervention or involvement by God at all, much less continuously, would not be a

perfect universe and so not the kind of universe that God would have created. We cannot think

that Leibniz did not realise this, and so do not find it a stretch to say that, in this context, by

“God” Leibniz meant “the universe that God created”. Indeed, since God would in any case

choose the best, why would he not create a universe that does so “on autopilot”? Autopilot

programmed or built in to the universe by God is many (perhaps infinitely-many) orders of

magnitude beyond ad lib “thinking on your feet” human creativity.

Answer to the question re second kind of choice: what God does from moment-to-moment

In short, God has to maintain the correspondence between souls or active substance, that is

incorporeal, and body which is passive substance and corporeal.

Leibniz objects to God being required to act at every moment, and thus explains that his

theory of pre-established harmony is superior to Descartes’ theory of occasional causes. Pierre

Bayle agrees. Yet Leibniz’s theory of ongoing choice of the best possible universe526 also

requires ongoing intervention by God though we have explained above how we prefer to

understand this. The difference is that pre-established harmony seeks only to explain the

movement of body under the action of soul/mind. God should not have to get involved in

mere body.

Leibniz’s explanation of the ongoing choosing of the best possible universe must leave the

laws of physics to work as they do, while allowing God to make the “choice” that remains of

the still-infinite possibilities even with the universe constrained by the laws of physics. The

only intervention needed is to maintain the pre-established harmony. That is, “to change the

natural course of the thoughts of the soul to adapt them to the impressions of the body” and

526 Monadology, §53

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vice-versa.527 God could choose to tamper with the pre-established harmony, and presumably

not impact the functioning of the laws of physics at all, but chooses not to because it would

derogate from the universe functioning in the best possible way.

This is an enormously significant point that cuts across theology, morality, psychology and

physics. If a human (or animal or bacterial) soul had a thought or intention that was not given

effect to in the corporeal realm, then not a scientist in the world would notice. Yet it would

make a very real difference to phenomena in the corporeal world. What, indeed, should that

correspondence be between a thought and an action? Is it possible to define the

correspondence as a mathematical relation? Leibniz argues that God links thoughts with

actions in the best possible way.

Creating the universe anew in each moment

Arguably, Leibniz remains true to his dictum that a universe that requires God’s ongoing

intervention would be imperfect, while allowing that God does have an ongoing influence

over creation.528 The ongoing intervention is not of God but of soul monads. soul monads

have thoughts which collectively form a space or a field which is incorporeal. Each soul

monad’s thoughts impact the physical universe in the best possible way, indeed, causing

change in or of the physical universe. A different set or field of thoughts of soul monads

corresponds not only to a different universe because soul monads and their thoughts are part

of the universe, but also results in a different physical universe.

An entirely different universe would result if such an entirely new set of thoughts were

possible and if the best possible manifestation of those thoughts were an entirely different

universe. Of course, such an entirely different universe would need to be in conformity with

ideas. However, soul monads’ thoughts do not change very often and often move in lockstep

with one another – at least, those of human soul monads do – and thus we see correspondingly

little change in the physical universe.

There is ongoing change in soul monads’ thoughts creating a new space or “thought field”

causing change in the physical universe. We say “change” because it manifests as an

incremental “delta”. However, for Leibniz to be correct it cannot be mere change because

“change” implies a running or functioning or ongoing operation, which cannot require God’s

intervention and therefore cannot have a pre-established harmony since God has a hand in the

pre-established harmony. Rather, the universe is being re-created every moment according to

the thoughts of soul monads which act as a diktat on the physical universe in the best possible

way via the pre-established harmony.

527 Loemker, p.587, 6th last line of 1st paragraph 528 Leibniz, G. W. Second letter to Samuel Clarke 1715-16 paragraph 8, “I do not say the material world is a

machine or watch that goes without God’s interposition, and I have sufficiently insisted that the creation

wants to be continually influenced by its creator. But I maintain it to be a watch that goes without wanting to

be mended by him; otherwise we must say that God bethinks himself again. No, God has foreseen

everything. He has provided a remedy for everything beforehand. There is in his works a harmony, a beauty,

already pre-established.” in Loemker, p.679

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Soul monads individually are eternal and indestructible while their perceptions change as a

result of experience of each other and of the physical universe. Again, these perception-

change or thought-changing experiences are preceded by the action of God between body

(passive substance or physical matter, which includes manifestations of the thoughts of other

souls which is the only way we can experience or know the thoughts of other souls) and the

soul. While each monad (active and passive alike) is itself indestructible and eternal, the

nature of the universe and the way monads interact with one another is transitory and

dynamic. It is these changing relationships along with the dynamicism in the internal

perceptions of soul monads that characterise each new incarnation of the universe as a whole.

The way such “characterising” works is a function of the pre-established harmony. The pre-

established harmony needs to be investigated as a serious branch of metaphysics. Ultimately,

when our understanding is sufficiently clear, the pre-established harmony would become a

branch of physics. An analogy is that while H2O molecules do not change, the way in which

they relate to one another as well as their internal (energy) state can differ greatly. This gives

us the difference between ice, water and steam. Thus, individual monads can change greatly

in their interrelationships and internal state creating greatly different universes. The

differences of concern in this analysis is in the incorporeal (active or soul) part of the universe

as well as in the corporeal/physical (passive or body) part of the universe which is controlled

by the incorporeal part, as well as in the entire universe regarded holistically.

An open question is what soul monads are there aside from those of simple living organisms,

animals and humans? It may be that other soul monads are very close to being passive (i.e.

body monads) but because in their dullness they work in such large numbers and with such

uniformity (far moreso than the soul monads of, say, humans do) they have enormous

influence in the physical universe via the pre-established harmony. Such would be the source

of the “controlling” field of creation of stars, galaxies, their motion and evolution, and the

behaviour of cosmic radiation. All cosmic phenomena apparently involving passive (i.e. non-

living, inanimate) matter would fall in this category. Consistent with this is that, according to

Leibniz, there is no matter that is entirely inanimate. The identity and nature of these soul

monads – which correspond to non-living (in the conventional biological sense) body monads

– requires further investigation.

Is it “Hello Humphrey Appleby” or, Does God control everything while appearing not to?

If God controls in the best possible way the relations between monads, what actual role is

there for free will? It seems that God via the Best actually controls everything. The central

factor that God does not control is the internal perceptions and appetitions of monads. It is

only when these are clear and distinct that the relations between monads and thus

considerations of the Best come into play.

Our free will, and that of all soul monads to the extent that they are active/soul, consists in

our ability to choose what we focus on, our physical experiences (to the extent that we can),

our appetitions, our use of rationality in making interpretations and our intellectual input. Of

course, the extent to which any individual can make those choices is limited too, but that very

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limitation is itself a function of the pre-established harmony because the scope of those

choices is a function of interactions between our soul monad and other monads. Perhaps this

is why Leibniz advocated top-down policy towards structure society in such a way as to

maximise the positive intellectual and cultural potential of the common mass of people to

enable them to make superior choices for ongoing betterment of themselves and of humanity

as a whole.

Mystical theology

Leibniz’s essay “On the true theologia mystica”529 is notable for what it does not say about

God. However, it is very clear about what is not real. “Most knowledge and invention

[Tichten] belongs to the shadow way.”530 He says that, “Corporeal things are but shadows

which flow away, glimpses, shapes, truly dreams.”531 Leibniz later restates this in a letter

written in Hanover on 30 June 1704.532 He goes on, “Essential truth is in the spirit alone. But

inexperienced men take the spiritual for a dream and what is tangible for the truth.”533

Leibniz is neither Gnostic nor a mystic. In another place, he wrote that witchcraft and sorcery

are based on delusion or fraud. He wrote of what sounds like a description of transcendental

meditation, “There are some who imagine a world of light in their brains.” However, “this is

not the light but only a heating of their blood.”534 He says that those who claim to experience

mystical phenomena are only in an aberrant psychological state. We should try to “conserve

them in this beautiful frame of mind, just as one preserves a curiosity or a cabinet-piece.”535

Leibniz cannot even be said to be a Cabbalist, for he explains why the idea of the “universal

soul” is untenable.536

Leibniz is amending and extending the actual Theologia Mystica537 by Dionysius the

Areopagite (“Dionysius”). Leibniz’s title suggests that his intention is to supplant it. Due to

the status and institutional theological significance of Dionysius, it is likely that Leibniz is

being diplomatic and agrees with very little of it. It is too “mystical” for Leibniz. Dionysius is

emphatic about what we cannot know, and the uselessness of mind. It reads almost like a

manual in transcendental meditation in that it instructs the seeker to abandon mind, body and

everything that he has.538 However, in “On the true theologia mystica” Leibniz criticises “the 529 c.1690, Loemker pp.366-8 530 c.1690, Loemker pp.367 531 p. 368, emphasis added 532 p.536 first paragraph 533 Ibid., p.368 534 Ibid., p.367 535 Letter to Electress Sophia in 1691, footnote 4, Loemker p.369 536 “Reflections on the doctrine of a single universal spirit” 1702, Loemker, p.555 537 Dionysius the Areopagite, Mystical Theology http://www.esoteric.msu.edu/VolumeII/MysticalTheology.html

accessed 26 October 2010. Another translation is at

http://www.ccel.org/ccel/pearse/morefathers/files/areopagite_06_mystic_theology.htm accessed 28 June 2011

which is Parker, J. (trans.) Dionysius the Areopagite, Works London: James Parker and Co. 1897, transcribed

by Roger Pearse, Ipswich, UK, 2004. 538 “For by the resistless and absolute ecstasy in all purity, from thyself and all, thou wilt be carried on high, to

the superessential ray of the Divine darkness, when thou hast cast away all, and become free from all.”

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denial of self” saying that the only denial of self we should consider is hatred of our non-

being which is the source of sin. Sin does not come from God; rather, “original sin has arisen

in some creatures from their nonbeing and hence out of nothingness”.

For Leibniz, the incorporeal is subject to rational inquiry just as much as the physical universe

is amenable to experiment. However, Dionysius seems to deny all kinds of knowledge and

inquiry when he writes, “We pray to enter within the super-bright gloom, and through not

seeing and not knowing, to see and to know that not to see nor to know is itself the above

sight and knowledge.”539 Thus, Dionysius advocates removal of mind, which would certainly

have played a role in rousing Leibniz to write a response to counter Dionysius. On the

contrary, not only does Leibniz say that a human is something, but he also explains the nature

of self-knowledge: “The only self-knowledge is to distinguish well between our self-being

and our nonbeing.” Furthermore, “one must make use of sensual things and must view the

shadow pictures only as an aid or a tool and not rest in them.”540

For Leibniz, it makes sense to inquire into the nature of God and, indeed, it is necessary to do

so to progress in science. However, Dionysius has made the concept of God entirely mystical.

Leibniz also writes that, “Essential truth is in the spirit alone. But inexperienced men take the

spiritual for a dream and what is tangible for the truth.”541 Dionysius does not agree that truth

is in the spirit but has detached the concept of truth from rationality. Indeed, it may be that

Dionysius is denying the concept of truth altogether though he does not explicitly say so; he is

certainly instructing the “adept” to abandon the pursuit of truth.

While, for Leibniz, “Corporeal things are but shadows,”542 he repeatedly says that what is

physically tangible or “body” must be used by humans as a tool to further advance our soul

which is to progress in understanding and intellectual capability. However, “God belongs to

me more intimately than my body”. Analysing body is effective in helping us to come up with

useful ways of doing things, which can help us in day-to-day life.543 In doing so, we can

follow Leibniz’s art of reasoning approach, which is not far from Newton’s prescription.

Likewise, in his concept of metaphysical substance or materia prima, Leibniz is using his

reductionist principle of his pragmatic “art of reasoning”.544 Leibniz finds it useful to

distinguish primary from derivative when in discussing forces545 and in discussing

phenomena.546 Using this method of reduction, Leibniz explains why the Cartesian concept of

extension is not fundamental. He explains that extension or distance and time are merely

relative ideas, in some ways anticipating Einstein and Einstein’s forebears in relativity

theory.547

Section I, Caput I “What is the divine gloom?” of Mystic Theology accessed at

http://www.ccel.org/ccel/pearse/morefathers/files/areopagite_06_mystic_theology.htm 28 June 2011 539 Ibid. 540 Loemker, p.368 541 Ibid. 542 Ibid. 543 Loemker, p.283 544 Wiener, pp.78-80 545 Loemker, p.537, 4th paragraph 546 Loemker, p.536, end of 1st paragraph 547 Letter to Burcher de Volder professor at the University of Leyden, 30 June 1704, Loemker, p.536

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Mathematical determinism

Yet 14 years later Leibniz refers to “phenomena” and “actual events”.548 This seems to be

shorthand for constituents of the physical universe as far as we can ever vouch for it. More

specifically, it seems to be the impact of ideals on substance. More accurately, it is the

adherence of the universe to the best possible because God has designed it that way. The “best

possible” happens to be in conformity with ideals. Why this is the best possible is a question

of huge importance, which is beyond the scope of this thesis.

Leibniz restates conformity of the laws of physics with ideals by saying that it cannot be

otherwise for nothing ever happens which violates any of the most exact rules of

mathematics.549 Paradoxically Leibniz does not think that mathematical determinism suffices

for an all-encompassing corpus of physics or of the unfolding of the physical universe. This is

due to:

(a) possibly, the self-affecting dynamical nature of the universe;

(b) the imperfect character of perception and the non-ideal decisions by monads that flow

from the appetite resulting from those imperfect perceptions;

(c) the creative ability of some monads which surpass other monads in their clarity and

distinctness of perception, and purity of their appetition; and

(d) the fact that God does not act purely according to mathematical rules.550

If we restrict consideration in (a) to passive substance, then its behaviour is likely to be

calculable provided we knew the exact location of every atom in the universe, and full

knowledge of every possible metaphysical and mathematical rule. Of course, this will never

be possible for humans, but we can comprehend that it might theoretically be possible.

An example of (b) is the result of geopolitical manipulations leading to humans blowing each

other up in a senseless war. An example of (c) is humans improving upon nature by, for

example, redirecting a river to bring life to a portion of desert. These are by definition outside

what can be addressed by ideals, and metaphysics and mathematics are restricted to ideals.551

In other words, perception and all that depends on it is inexplicable on mechanical grounds.552

Perceptions are no small consideration even though they are outside the corpus of

deterministic textbook physics, which only even attempts to address efficient causes.553

548 Loemker, p.536, end of 1st paragraph 549 Loemker, p.583 550 God is not like “the blind nature of the mass of material things, which acts according to mathematical laws,

following an absolute necessity, as the atoms do in the system of Epicurus.” Theodicy, p.399 §8. Yet the fact

that he acts for the best has a certain comprehensible and reasoned harmony to it, if not “absolute necessity”. 551 On the other hand, the example in (b), for Leibniz, might lead to something better, just as Westphalian

sovereignty followed the 1648 Treaty of Westphalia which concluded the Thirty Years War. The example in

(c) is humans acting like the divine in improving the universe and enhancing its plenitude. 552 Monadology, pp.228-9 §17 553 Loemker, pp.639-640 §11

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Indeed, only perceptions can be found in a simple substance554 which is a created monad.555

This class of influences on the universe is called final causes.556 All internal activities of

created monads are a result of perceptions which are also a kind of thought or mental image

or notion. Each created monad is independent of everything as if there were nothing in the

universe but itself and God. This is notwithstanding the fact that every monad perceives every

other monad, since perception is not the same thing as direct influence. Apparent “influence”

of a monad on another (e.g. of a person holding another in their thrall) is actually the latter

monad voluntarily pursuing the perceptions of the former or having their perceptions

manipulated by the former; in common parlance, the latter has ceded its will or personal

sovereignty to the former.

Another way of considering (b) and (c) are that God’s raw material is us, along with monads

below and above us. He needs to wait especially for us and monads above us to improve, and

gives us every conceivable opportunity to do so without violating our free will. He would not

force us because that would not be the best way. The way this unfolds leading to our realising

our co-creative ability is outside metaphysics and mathematics, but is a function of the

“thought process” of a monad.

How can this thought process be improved to help along God’s intention for the universe? Of

course, the Universal Characteristic as Leibniz conceived it would aid thought. The Universal

Characteristic can now be regarded as a means whereby some of the most powerful

fundamental constituents of reality – active monads or minds – can empower themselves to

fulfil their function even more effectively. First, the Universal Characteristic must encompass

the discovery and use of metaphysical principles and mathematical rules. To be complete it

must be able to assist or systematise calculations with both (b) and (c), and accommodate

problems with respect to those. Somehow, (d) needs to be taken into account too. To

understand (d), we need to understand the question under the above subheading “Unanswered

question re second kind of choice”.

Is everything planned in advance?

That creation should unfold in the best possible way is pre-ordained because this is built into

the design of the universe. At the same time, there cannot anyway be sudden and bizarre

changes due to the principle of sufficient reason. Human free choice adds a certain amount of

variability, within a particular range. If we had perfect knowledge, then we could forecast how

things are going to work, subject to (or modulo) the free choice of human souls and all the

other soul monads in the universe. With any given amount of knowledge, the best choice in a

given scenario is deterministic. Thus, if we knew all that was important to a person and what

their inclinations were, then we would know in advance what they were going to decide. As

mentioned in the above section “Creating the universe anew in each moment”, soul monads

do not change their thoughts very significantly very often though over time there can be huge

554 Monadology, p.228 §17 555 Monadology, p.229 §18 556 Loemker, pp.639-640 §11

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changes. Of course, there are decisions that can be made randomly or without reason.

However, these have little impact on the overall course of history.557 The large changes on

history are caused by changes in the “thought field” of large numbers of monads, which of

course are sparked by insights had by particularly active soul monads such as that of Christ.

In the sense that the architectonic design allows us to foresee what will happen provided we

have perfect knowledge of all facts and all possible ideals, yes.558 But note that this is much

harder than it might sound. We would need to know the internal perceptions of all created

monads, and know which outcome will produce the best possible conditions for

improving/clarifying their perceptions. We will also need to know the impact certain

experiences will have on these perceptions, and their perceptions of their own and of other

monads’ perceptions, the best possible choice from that point, and so on. In short, we would

need to be God.

A priorism

Leibniz makes an art and a science of reading God’s mind. This is because it is rational to do

so since God is the Creator, and because it is possible to do so as God’s mind is rational.

“Reason is also choice” says Milton in Paradise Lost.559 Aquinas also makes an art and a

science of reading God’s mind.560

Leibniz says that the best science is done by attempting to read God’s mind like Cusa and

Einstein did.561 Experimental results are useful to confirm or deny what we think that God

would have done, or to check the accuracy of our reasoning, much as we would check our

accuracy in carrying out a long and complicated piece of arithmetic.

Science is a result only of our ability to grasp demonstrable truths such as in logic, number

and geometry for they “make the connection of ideas indubitable and their conclusions

infallible”.562 “The mathematical sciences, moreover, which deal with eternal truths rooted in

the divine mind, prepare us for the knowledge of substances.”563

Is a priorism better than empirics?

557 Loemker, p.640 §13 first paragraph, and Loemker p.641 §16 first sentence 558 Loemker, p.640 §13, 1st paragraph 559 Milton, J. Paradise Lost Book III, line 108 in Ricks, C. (ed.) Paradise Lost and Paradise Regained The

Signet Classic Poetry Series, The New American Library, New York 1968 560 See Thomas Aquinas’ Summa Theologica accesssed at http://www.newadvent.org/summa/ 26 May 2011 561 For Cusa, see De Docta Ignorantia and Idiota de Mente, and for Einstein see

http://web.ceu.hu/yehuda_einstein_and_god.pdf accessed 30 Oct 2010 562 Loemker p.638 §5 563 Loemker, p.592 (Letter to Hansch, July 25, 1707)

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Yes, when it is available to a human mind.564 However, it is rare that any human’s

“intellectual perceptions” (i.e. the internals of any created monad belonging to a human) are

clear and distinct in anything. All created monads are nearly always confused and indistinct in

their perceptions with respect to all things. Even in the angels and blessed “there is always

some confused perception mingled with distinct knowledge”.565

How could innate truths regarding topics other than physics – i.e. outside of metaphysics and

mathematics – ever be found through empirics?566

Leibniz’s “empiricism” is simply that sensory observation prompts thoughts and checks

reasoning, including the soundness of reasoning. “The external senses, properly speaking, do

not deceive us. It is our inner sense which often makes us go too fast.”567 Empiricism says

that the senses give us knowledge and that thoughts are only needed to organise the

knowledge that the senses give us. This is at odds with Leibniz’s position as explained in New

Essays.568

For humans, ideas and empirics are interdependent

Similarly, entirely detached from sense perception, ideas are not possible. At least, we never

have ideas that are so abstract that they are entirely disconnected from sense perception.569,570

Is this effectively saying that we can never hold a pure idea in our mind, but only something

mixed with empirics? Perhaps not. Leibniz says in New Essays that we already know a great

deal. It is sense perception or general experience that draws it out of us or which triggers

thoughts from our memory. In this, Leibniz follows the doctrine of reminiscence from Plato’s

Meno.571 As we will explain below, if we have one Idea within us, then we probably have all

ideas within us, with varying degrees of distinctness. This is not surprising because “each

distinct perception of the soul includes an infinity of confused perceptions which envelop the

564 Recall the above footnote regarding Plato’s view on reason versus sense perception. In The Republic (602 d),

Plato says, “A stick will look bent if you put it in the water, straight when you take it out, and deceptive

differences of shading can make the same surface seem to the eye concave or convex; and our minds are

clearly liable to all sorts of confusions of this kind.” 565 Theodicy §310, p.314 566 Bennett, J. (trans.), Leibniz, G.W. New Essays on Human Understanding , pp.97-99 and Chapter III, 1st ed.

Feb 2005, amended April 2008. Accessed at www.earlymoderntexts.com/jfb/leibne.pdf 10 May 2011 567 Theodicy §65, p.109 568 Bennett, J. (trans.), Leibniz, G.W. New Essays on Human Understanding Book IV Chapter XII §13

“Philalethes: Although I recommend experimentation, I don’t lack respect for probable hypotheses; they can

lead us to new discoveries and are at least great helps to the memory. But our mind is very apt to go too fast,

and to be content with flimsy conjectures rather than taking the time and trouble needed to test them against a

multitude of phenomena.” 1st ed. Feb 2005, amended April 2008, pp.212-213 Accessed at

www.earlymoderntexts.com/jfb/leibne.pdf 10 May 2011 569 Ibid., p.19 570 Hermes writes, “Both sensation and understanding flow together into humans, intertwined with one another,

as it were. For without sensation it is impossible to to understand, and without understanding it is impossible

to have sensation.” Corpus Hermeticum IX §2 in Copenhaver p.27 Even Plato’s Meno, written centuries after

the Corpus Hermeticum, bears this out because the uneducated servant boy is given prompts in the form of

appropriate questions and a diagram to aid him in “remembering” geometrical truths. 571 Langley, G.A. (trans.), Leibniz, G.W. New Essays on Human Understanding Open Court, La Salle, Illinois

1949, p.105

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entire universe.”572 Similarly, “Each soul knows the infinite, knows everything, but

confusedly.”573

If one rejects the idea of remembering things that we already knew, then the need for

experience to trigger thoughts which lead to ideas might mean that the domain of ideas is

actually bound up with the impressions on our senses that, by definition, can only occur in the

physical universe. This leads to the “sufficient reason” for the existence of the physical

universe.

That no human thought is ever entirely abstract might encompass the fact that humans

“experience” or “conceive” ideas in a cultural context. Perhaps it is merely the perceived

context, whereas the idea itself is universal and objective. Perfect objectivity is not possible

for humans, and different cultures facilitate the conception of the universe in different

ways.574

Free will

Gose in his discussion of right reason refers to the removal of choice by addictions to

pastimes such as drinking and smoking.575 This is how Gose explains that the corollary of

Milton’s concept of “right reason” is that only the wise can be free. “With his accent on

liberty and freedom, Milton is quick to affirm that liberty is not license. … Milton asserts that

with the ‘dignity and freedom of individual man’ comes a responsibility for individual

discipline.” The addict cannot exercise that discipline.

Leibniz would agree that only the wise are truly free. However, this is because they have a

greater appreciation of what will lead to true happiness, which is pursuit of God’s mind. Thus,

we would say that Milton meant that “To exercise Reason is also choice”576 and the wise tend

to choose to.

Gose makes a couple of other useful remarks. He says that “The classicists as well as other

non-Christian thinkers” do not deny that Reason is a source of (i.e. a source of knowledge

of?) God. But, Gose says, “it is limited by human imperfection.” This echoes Nicolaus of

Cusa. Next, Gose says, “Milton says that the unwritten law of God: is no other than that law

of nature given originally to Adam, and of which a certain remnant, or imperfect illumination,

572 Loemker, p.640 §13 1st paragraph 573 Loemker, p.640 §13 2nd paragraph 574 There is evidence that the way that the “plastic brain” is structured is partly a result of culture, causing

physically different wiring of synapses between cultures. Thus the question goes beyond sense perception but

to what the term objective means and what it means to think; these concepts might have different meanings to

radically different brains. This does not mean that ideals differ between minds, but perceptions of ideals

could differ with the resultant conclusion that what a particular mind perceives as idea I is in fact idea J or is

K which is not an idea at all. Refer to Doidge, N. The Brain That Changes Itself: Stories of Personal Triumph

from the Frontiers of Brain Science Penguin 2007 575 Gose, M. Right Reason: Milton’s Ethical Standard

http://globalvillage.pepperdine.edu/GoseWriter/rreason.html accessed 4 October 2010 576 Milton, J. Paradise Lost Book III, line 108 in Ricks, C. (ed.) Paradise Lost and Paradise Regained The

Signet Classic Poetry Series, The New American Library, New York 1968

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still dwells in the hearts of all mankind; which, in the regenerate, under the influence of the

holy spirit, is daily tending towards a renewal of its primitive brightness.” Here we see the

Platonic-cum-Leibnizian memory of what the soul already knows, but by a different method.

Gose says, “The classicists as well as other non-Christian thinkers … are in need of divine

revelation and love to complete their search for truth.” One could be forgiven for reading

Cusa in this way, and perhaps this is what Cusa meant. It is certain that Cusa believed we

could never equal God. However, contrary to Cusa,577 Leibniz is clear that divine revelation in

the sense of a mystical enlightening or a rapturous experience is no way to achieve

knowledge. We might sometimes feel that that is how we are discovering – or recalling –

something, but in fact it is a process of Reason, and not necessarily a deductive one, that gets

us there. On the other hand, if we are remembering, then perhaps there is a place for

revelation though Leibniz never allowed for it.

To Leibniz, there is no such thing as freedom in the sense of liberalism or of “licence”.578

Leibniz often used the pejorative barbarism. However, he also noted that men from all

cultures have a sense of justice even if they do not apply it to all things and times or to the

extent that Christians do or would if they followed Christ’s teachings all the time. In New

Essays he gave the example of the barbarisms of the native Indians of America and of some

native tribes of Peru, but noted also that in some matters those peoples adhere to the same

standards of justice as Christians of Europe.

What is an evil person?

An “evil person” is a soul monad with perceptions that are contradictory to ideas. One may

ask, “Contradictory to which ideas?” The answer is, “To all ideas.” Remember that “idea” has

a specific meaning for Leibniz. They are not merely thoughts or concepts. An idea is correct

by definition, and to be “correct” it must be consistent with everything that exists and has ever

existed. An evil person is further away from ideas than a good one.

This definition encompasses moral wrong, and deliberately emphasizes that moral truths are

as much subject to rational proof as a mathematical principle may appear to be. Perceptions

contradictory to ideas may have a degree of clarity and distinctness greater than many “good”

soul monads have of concepts that bear some resemblance to ideas. To anticipate how Leibniz

deals with the problem of: It is the clarity with which the evil soul perceives what is

contradictory to ideas that forces other soul monads to clarity and drive their own conceptions

closer to clear and distinct perceptions of ideas.

577 Nicolaus of Cusa wrote that he experienced an epiphany during a sea voyage, in which God opened up his

understanding. 578 Echoed by Alexander Hamilton http://www.catholiceducation.org/articles/history/us/ah0015.html accessed 4

Oct 2010 “Freedom was a great treasure, Hamilton agreed with the ideologues, propagandists, social

engineers, and manipulators of all ages, but it must be organized against abuse. Unrestrained man’s freedom

degenerated into license and anarchy.”

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“Evil” soul monads are active just as are “good” soul monads, and so are superior in to and

able commandeer more passive monads and passive matter just as well as the good souls are,

if the more good souls allow them to. The definition of an “evil” soul monad is that it works

in contradiction to ideas or relatively so in comparison to “good” soul monads. Thus, nothing

that evil soul monads do can last, thought they have can cause destruction indefinitely as long

as they are allowed to before that uplift themselves, or are uplifted by more correct

perceptions, i.e. by perceptions that are closer to ideas. Since only ideas can exist, evil works

in conformity with non-being or nothingness, which is precisely what Leibniz wrote in “On

the true theologia mystica”.579 That is, sin is not from God but from nothingness or the non-

being of certain creatures.

In order to wreak havoc, evil soul monads make use of discoveries that have been made in

conformity with ideas, which permit machines of control and weapons of destruction all of

which arise from engineering and science. Leibniz wrote that a bad European is much worse

than a bad tribal native because the bad European has at his disposal all the power arising

from the positive scientific culture of European civilisation.

The problem of evil

One of the most frequent criticisms of Leibniz’s system of metaphysics is his “best of all

possible worlds” doctrine which is actually a consequence of the principle of sufficient

reason. If this is the best of all possible worlds, then why does evil exist? Davies raises this

objection to the “Leibnizian optimism” but leaves it aside as an “ethical issue”.580 Yet it is

clear that question of justice, goodness and morals generally are as much a part of ideas and

the workings of “the mind of God” as are metaphysical principles and mathematical rules.

Davies then considers “maximum variety” as a substitute for “the best”.581 This might better

have been considered under Leibniz’s doctrine of plenitude.582 Nonetheless, Davies pursues a

promising line of enquiry when he considers beauty as a guide to truth.583

Leibniz explained that the truest and most enduring happiness comes from pursuing the

understanding of the whole which ultimately means the mind of God.584 However, this pursuit

must be free in order to be fruitful. Thus, evil is expected in this pursuit but those minds

which know better are likewise free to best the proponents of evil conclusions reached

through misguided reasoning, and to struggle against those forces and attain supremacy over

them.

Erasmus is close to Milton on free will, e.g. “exhortations, commands, choice, reward and

punishment, all present in scriptures with respect to salvation, would be meaningless in the

579 ca.1690, in Loemker pp.367-370 at p.368 580 Davies, P. The Mind of God Penguin Books Camberwell Victoria 1992, p.173 581 Ibid. 582 Kepler refers to plenitude in passing when he says that “mere space without body is a contradiction” and

“Being has precedence over not being”. M.C., Chapter XI, p.129 Duncan, trans., Abaris Books 583 Davies, P. The Mind of God Penguin Books Camberwell Victoria 1992, p.175 584 We return to this below under the heading “Interdependence of ideas”.

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absence of free will.”585 This is precisely what Milton has God say to his Son in Paradise

Lost.586 Leibniz’s explanation of free will befits his rationalism and best of all possible worlds

doctrine, whose corollary is that people tend to make the best decision they can at any given

juncture, and the outcome however good or bad leads us to a wiser or otherwise better state in

the end. Leibniz even says that a murder will ultimately lead to something better than had the

murder not taken place. However, he also takes pains to emphasise that this does not mean

that those who do wrong should not be punished – they should. However, he says, ultimately

sin punishes itself anyway. The past has occurred for the best but we must not acquiesce in the

present for the future as the quietists advocate; we should always do our best.587

Also see the effect of evil and what God permits.588 God does not accidentally allow evil to

occur; he does provide the tools or circumstances which can be used for evil undoubtedly

knowing that this “risk” exists.589 God permits evil because he can bring a greater good out of

it. The whole of creation actually derives a net gain from evil.590 Moreover, Leibniz seems to

be saying that certain kinds of good would not be possible at all were it not for evil. Leibniz

does not see the relationship between good and evil as a balance sheet, where we allow evil to

debit us one unit so we can be credited two units worth of good. Rather, evil can trigger

entirely qualitatively new categories of good and catalyse possibilities for good that would not

otherwise have been considered or embraced.

We can hearken back to Milton’s Paradise Lost, where God says to his Son that Satan should

not be stopped from carrying out his plan. Humans need to be left free to choose whether they

shall yield to temptation or not. Given the reality of free choice, the inevitable result is that

some humans will yield to temptation while some will not and innocents will necessarily

suffer. This evil is not merely accidental or part of an optimisation but is an intended and, in

view of the whole, a good result which works for the betterment of the innocents as well as

those who yielded. Perhaps innocents are not innocent, for all must take a responsibility for

the whole.

Leibniz writes that he cannot “approve the opinion of certain moderns who maintain boldly

that what God has done is not supremely perfect but that he could have done much better.”

Rather, he holds that, “God does nothing for which he does not deserve to be praised.”591 So

does God deserve to be praised for the starving children and the murderers and rapists?

Leibniz addresses this when he asks, “Why does such a Judas, who is merely possible in the

idea of God, actually exist?” about which he says, “no answer can be expected here on earth,

585 From http://www.siue.edu/~evailat/psr-Lut-Er.html accessed 4 Oct 2010 586 Milton, J. Paradise Lost Book III, lines 100 to 130 in Ricks, C. (ed.) Paradise Lost and Paradise Regained

The Signet Classic Poetry Series, The New American Library, New York 1968 587 “We must rather act in accordance with the presumptive will of God, so far as we are able to know it, trying

with all our might to contribute to the general welfare…” with emphasis in the original. (Loemker, p.305 §4) 588 “Discourse on metaphysics” 1686 in Loemker, p.307 589 Leibniz writes that it is, “true that God co-operates in evil in the actual performance of introducing these

forms into matter” Theodicy, p.353 §381. Separately, Leibniz explains, “how it is to be understood that God's

will takes effect, and concurs with sin, without compromising his wisdom and his goodness.” p.399 §8 590 “On the true theologia mystica” c.1690, Loemker p.368 591 “Discourse on metaphysics”, Loemker, p.304

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except the general one that since God has found it good that he should exist in spite of the sin

which God foresaw, this evil must be compensated for with interest in the universe and that

God will draw a greater good from it and that it will turn out finally that this sequence of

events, including the existence of this sinner, is the most perfect among all other possible

kinds.”592 Evil plays the role of revealing the good and, over time, we step back in order to

leap forward better.593

Leibniz’s conception of evil is more as natural imperfections that are an inevitable part of the

process of upwards evolution or moral upshift, ultimately leading to every kind of

improvement, enrichment and increased power. Ultimately, when realised in human

endeavour, such upshifts includes kinds that are perceptible in the physical universe through

projects such as those discussed in Chapter 3. So for Leibniz the defining characteristic of evil

is not that which is judged as such by God, but it is more closely linked with that which has a

role built into the design of the universe, just as that which is good has such a role.

Scientific comprehensibility of God’s plan

While we are identifying Leibniz as a Neoplatonist – as he says “I tend more towards Plato,

Mr Locke to Aristotle” but on some things we differ from both of these great ancient writers –

we must note that Leibniz is more rationalist than anyone before him.594

If there are two things we can take away from New Essays, the first is that all is

comprehensible. The universe was made in such a way that if a mind knows all or is admitted

into the secrets of things, then there will be reasonable explanations for things and all will be

understood. Second, the discovery process is a remembering of what the soul already knows.

Hill argues that “Leibniz’s views of intentionality are closely bound up with key elements of

his metaphysics and epistemology – especially his understanding of relations, his commitment

to the explanatory power of theism and the role of the divine ideas”.595

The objective way in which God works embodied in the architectonic universe is probably

Leibniz’s most significant contribution, and we would argue that this is rationalism. What

Kepler discovered and described for the solar system, Leibniz explained for the universe in

toto. In fact, Leibniz continued Kepler’s programme of, in Franklin’s words, constructing a

theory of everything.596

592 “Discourse on metaphysics” §30, 1686, Loemker 1969 p.322 593 “Reply to Bayle’s Dictionary article Rorarius”, 1702, Loemker 1969 p.582 594 Leibniz’s Preface to his New Essays Concerning Human Understanding, p.2 595 Hill, J. C. R. Leibniz’s metaphysics of intentionality PhD Thesis, National University of Singapore 2008, p.3,

viewed 27 August 2010

<https://scholarbank.nus.edu.sg/bitstream/handle/10635/16595/HillJCR.pdf?sequence=1> 596 Franklin, J. The Science of Conjecture: Evidence and probability before Pascal J. H. Press Baltimore and

London 2002, pp.150-1

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In New Essays it is very clear that God would not create the universe in any way other than

the best. Thus, the universe could not be otherwise than as it is. Therefore, we study the

universe as it is (i.e. do science) by reference to that, not to God per se. However, we can

come up with hypotheses by considering (the) perfection which is God’s nature – and all the

(other) characteristics that God necessarily must have. Writers like Wenck would say this is

“constraining God”. God’s nature, however, is to act for the best. There is a mathematical

kind of certainty to how God would act, but our reason is so clouded and our knowledge so

miniscule that we are infinitely far from knowing or understanding “the best”. The concept of

“the best” is an objective one and is just as discoverable as any of the ideas. We are still using

the strict definition of “idea”.

While ideas are perceived in the mind of God, it is likely that everything we think is an idea,

in fact, is not. Indeed, each idea is bound up with the entire universe and cannot exist or be

understood except as part of the entire universe. Only God can hold the entire universe in

mind in a single thought. Do ideas actually exist? As discussed above, according to Leibniz,

ideas so do not exist even though they are perceived by the mind of God or held in God’s

mind. Ideas are realized or manifested in the physical universe. Indeed, ideas are all that is

manifested in the physical universe: this is one of the definitions of an idea.

Intention and the Scholastic Leibniz project

The closest we get to a Platonic world of ideas in Leibniz is the “intelligible world in the

divine mind, which I also usually call the region of ideas”.597 We know that they have the

effect of defining the best. However, it is only a “world” in the sense that God has a lot of

ideas in his mind at once. A capable human mind could also have in it a world of ideas.

Hill argues that the scholastics believed in the existence of such a domain of ideas:598

the scholastic philosophers developed a “package” of metaphysical claims which

underlay a common approach to intentionality. These claims were that relations have

reality outside the mind; that God’s ideas function as exemplars of their objects; and

that the mind abstracts “intelligible species” from the objects of perception. These

views allowed them to defend the intuition that a thought of X is linked to X in some

way by the relations of both similarity and causation. … Leibniz held views that were

structurally similar to the [scholastic] “package”, which allowed him to hold a similar

approach to intentionality.

According to Hill,599 the scholastic theory of intentionality was supported by three primary

metaphysical doctrines:

1. “Ideas” function as exemplars, and are located primarily in the divine understanding.

2. When the active intellect contemplates something, it actually takes on the same form

or species as that thing.

597 Loemker, p.592 (Letter to Hansch, July 25, 1707) 598 Hill, J.C.R. Leibniz’s metaphysics of intentionality PhD National University of Singapore 2008, p.iii 599 Hill, J.C.R. Leibniz’s metaphysics of intentionality PhD National University of Singapore 2008, pp.8-9

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3. Relations, or at least some relations, exist outside the mind and cannot be reduced to

monadic (or atomic?) predicates.

Each of these contradicts Leibnizian ideas in various ways. Each of these contradicts

Leibnizian ideas in various ways. Taking each of the points in turn:

1. For Leibniz, an idea is a concept that is consistent with the entire universe and so is an

expression of the entire universe. An idea is not located in the divine understanding or

anywhere. An idea has no location. It is true that only the divine understanding can

ever grasp an idea because only the divine understanding can grasp the entire universe

in a single thought. Human understanding can approximate ideas but never fully.

2. The intellect, active or otherwise, never takes on the form as a thing that it

contemplates. The intellect is an active monad or a thing in its own right. An active

monad – meaning, a mind – can have impressions of things upon it which are nothing

but perceptions.

3. A relation is itself a concept that might approximate reality to the extent that its

predictions are confirmed by goings-on in the physical universe. A concept only exists

as a mental perception. If a relation did exist outside the mind, like anything that exists

outside the mind, it would be part of the physical universe. Once we accept that

something is part of the physical universe, it is no longer a mere concept and therefore

cannot be a relation. The concept of relation is merely a thought tool to help us

advance our concepts closer to the likeness of ideas.

Hill’s project of demonstrating Leibniz’s use of or, at least, agreement with scholastic ideas is

not isolated in the literature. In his 1686 “Discourse on metaphysics” Leibniz wrote, “the

opinions of the Scholastic philosophers and theologians are much sounder than has been

imagined, provided that they are used appropriately and in their proper place. I am even

convinced that if some exact and thoughtful mind were to take pains to clarify and assimilate

their thoughts after the manner of the analytic method of geometricians, he would find a great

treasure of very important and strictly demonstrative truths.”600 Farrer says that Leibniz was a

scholastic but was bent on reforming if not rewriting scholasticism.601

Leibniz notes with approval that Scholastics at one time expressed that God is the light of the

soul. Thus, Leibniz is actively looking for areas to agree with the Scholastics.602

As far as intention goes, it seems that the ultimate or umbrella intention of all is God’s. We

only have ideas of things in our soul because of God’s continuous action on it. Further, as

already discussed, ideas are all that we have that can cause phenomena (in fact, to which

600 Loemker, p.309 601 Farrer, A. (commentator), Huggard, E.M. (trans.) Theodicy, p.12 602 “God is the sun and light of souls … and this opinion has not been invented only today. In addition to the

Holy Scriptures and the Fathers, who were always more Platonists than Aristotelians, I recall having

observed long ago that at the time of the Scholastics, several believed that God is the light of the soul … ‘the

active intellect of the rational soul’. The Averroists gave this a bad turn of meaning, but others … understood

it in a way worthy of God and capable of elevating the soul to a knowledge of its true good.” (“Discourse on

metaphysics” 1686 §28, Loemker, p.321)

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phenomena correspond because phenomena are the best possible, to be explained further

below under the final heading in this chapter before the conclusion) as notions are too

indistinct.603

When we say ideas “cause” phenomena we mean, in fact, to which phenomena correspond

because phenomena are the best possible. This is explained above under the headings:

Ideas and “the Best” are outside all that exists

The apparent ruling of actual things by ideas

and below under the heading:

Foundations of a programme for discovery.

The apparent physical world as far as we can tell has been provided as a way to help our

indistinct and confused intellect come up with ideas or remember ideas that it has always had

within it, but which in some cases have never been brought to the conscious fore of the mind.

As we know from our experience, real ideas are usually bound up with moral purpose and a

kind of detached, i.e. not heatedly emotional, passion.

Regarding relations, Hill says that Leibniz’s “apparently contradictory statements about

relations can best be understood by distinguishing between two kinds of relations in his

thought. He thinks that relational properties have extra-mental reality, but ‘inter-substantial’

relations do not, and are mere abstracta. In this, Leibniz is very similar to his scholastic

forebears.” It would appear plain that relational properties exist beyond the mind due to the

reality of the things of which they are properties. On the other hand, “inter-substantial”

relations do not have a reality beyond the mind because they are not real since all substances,

i.e. all monads, are independent (despite their being the same and being in constant inter-

communication).

Hill writes:

Leibniz speaks about God’s ideas a great deal – not just those of human beings – and

assigns them a part-cause in creation, with a deliberate appeal to Augustine. These

ideas are conceived in a fundamentally relational way. Leibniz rejects Malebranche’s

identification of our ideas with God’s, but he does think there is some important

connection between them; for us to have an idea is to exist in some relation to God’s

ideas.

However, that relation does not seem to be any different from the relation between two souls

having the same idea. For example, if Jack and John both prove that the angle sum of a

triangle is 180° then there is a relation between their minds when both have the image of that

idea in their mind.

Hill writes:

I argue that an interpretation of Leibniz as a nominalist about ideas, which has been

defended by some recent commentators, is not accurate. 603 Leibniz, G. W. “Discourse on metaphysics” 1686 §28, Loemker, p.321

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Leibniz himself seems to be in support, “As long as we have only a nominal definition, we

cannot be sure of the consequences drawn from it, for if it concealed some contradiction or

impossibility, we could draw conflicting conclusions. This is why truths do not depend on

names and are not arbitrary, as some modern philosophers have thought.”604 However, recall

that to not be a nominalist is to believe either universals exist or abstract objects exist in a

Platonic sense.605 Leibniz believes neither of these and therefore is not a nominalist. Believing

we are forced inexorably to conclusions that are correct or true is different from believing that

truths exist as real objects. Rather, as explained when Leibnizian ideas were introduced, what

is an idea is bound up and ultimately defined by the totality of the best of all possible

universes.

Continuing with Hill:606

According to this [nominalist] interpretation, Leibniz believes that to have an idea of

something is simply to have a disposition to think about it. I argue, however, that this

is only Leibniz’s understanding of ideas when they are not being thought of; when

they are being thought of, they are objects of thought.

It is unclear what an “object of thought” is. However, Leibniz does not take an “idea to be an

immediate object of thought or for some permanent form”.607 Leibniz says that our mind can

manifest whatever it desires to itself, “As a matter of fact, our soul always does have within it

the disposition to represent to itself any nature or form whatever, when an occasion arises for

thinking about it.” This makes thought akin to a “phantasm”.

Hill writes:608

Moreover, the divine ideas certainly cannot be understood dispositionally at all. In

fact, the divine ideas are identical with their objects, a claim which is fundamental to

Leibniz’s overarching argument in the Theodicy. Here again, there are strong

similarities between Leibniz’s position and that of the scholastics.

…

Leibniz distinguishes between “a” concept of something and “the” concept of the same

thing; the latter is identical with God’s idea of that thing, which is also identical with

the thing itself.

We would disagree that in Leibniz’s analysis God’s idea or concept of a thing is any more real

than a human mind’s idea or concept. An idea is not a real thing but a mental perception of

real or potentially real things. Leibniz distinguishes mental images, even God’s mental images

of ideas, from real things. Thus, divine ideas cannot be identical in the sense of being the

same as their objects, for a mental image cannot be real. Leibniz distinguishes a mental

image, even God’s mental images of ideas, and real things.

604 Leibniz, G. W. “Discourse on metaphysics” 1686, Loemker p.319 605 Rodriguez-Pereyra, G., “Nominalism in Metaphysics” Stanford Encylopedia of Philosophy Zalta, E.N. (ed.)

Article first published 2008 and substantially revised 2011 accessed at

http://plato.stanford.edu/entries/nominalism-metaphysics/ 28 July 2012 606 Hill, J.C.R. Leibniz’s metaphysics of intentionality PhD National University of Singapore 2008, p.10 607 Loemker p.320 §26, lines 6-9 608 Hill, J.C.R. Leibniz’s metaphysics of intentionality PhD National University of Singapore 2008, p.11

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Leibniz is strict about what it means to have an idea. “One can boast of having an idea of a

thing only when one is assured of its [the thing’s] possibility.”609 Leibniz also writes, “it is

obvious we have no idea of a concept when it is impossible.” Further, “in the case of merely

suppositive knowledge, even if we may have an idea, we do not grasp that idea, for such a

concept is known only in the same way as are those concepts which involve a hidden

impossibility; even if it is possible, we cannot learn of its possibility by this way of knowing

[i.e. by supposing it is so].”610

Overall, Hill is looking at the pieces of Leibniz’s philosophy and letting us know where it

seems to be scholastic. The overall intention of Leibniz differs from the overall intention of

most scholastics. Leibniz as a self-described “more Platonic than Aristotelian” thinker

undoubtedly adopted some ideas similar to the scholastics and in some cases fully agreed with

the scholastics.

Hill discusses the kinds of ideas that Aquinas says that God can have - i.e. T-ideas (ideas as

types) versus TE-ideas (ideas as types and as exemplars).611 Hill’s discussion around Aquinas

misses the fact that God acts for the best because it is in God’s nature to do so. God is not

impelled by nature but by his own nature, albeit that his nature is to act for the best; thus, we

see ideas in what becomes the laws of physics (i.e. nature) only due to God’s nature.

God’s thoughts are made real by his will

Upon thinking of something, for God to will it is for it to become real. Thus, intention for God

is a very different matter from intention for humans. At the same, while action not will alone

is needed for humans, action is a result of will. As far as the soul is concerned, will is action

for the soul. Pre-established harmony causes the will of the soul, or a particular kind of will of

the soul, to invoke changes in the compound body monad which effects physical changes in

the universe.

God only chooses to will into reality thoughts that are in conformity with ideas. Could

humans act to bring into reality plans that are not in conformity with ideas? Of course, though

action by humans is much slower and more painstaking that will is for God.

We must leave open the possibility that there are ideas accessible by God that require faculties

that God has which humans do not and never will have. For example, God’s mind can

comprehend the entire universe and all of its possibilities in a single thought.612 This may well

609 Leibniz, G. W. “Discourse on metaphysics” 1686, §23, Loemker p.318 610 Ibid., §25 p.319 611 Hill, J.C.R. Leibniz’s metaphysics of intentionality PhD National University of Singapore 2008, pp.32-33 612 Friedrich Schiller reiterated this concept of a single act of thought: “Reason insists, in accordance with its

necessary laws, upon absolute totality of perception, and without letting itself be rebuffed by the necessary

limitation of the power of imagination, the mind requires from it a complete summation of all the parts of a

given quantum in one simultaneous mental image.” Johnson, S. trans. Of the Aesthetic Estimation of

Magnitude (1793) Accessed at http://www.schillerinstitute.org/transl/Schiller_essays/magnitude.html 1 Jan

2011

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open up an entire class of ideas which are of no practical use to humans without the capability

of instantaneous pan-universal comprehension. However, humans could presumably still

grasp and reason about the process, structure and harmony in the ideas used; it is just that we

could never make practical use of those ideas in the way that God does. We might still be able

to make practical use of those ideas for smaller matters. However, it might be possible that

there are some ideas that only make sense when the entire universe and all possibilities are

under consideration.

Thoughts that soul monads have

Ideas are the foundation of the unfolding of the universe even though ideas are not of the

universe or in the universe, nor of the immaterial realm of souls (which too is part of reality)

nor even part of God. Thoughts too are merely images or perceptions. Nevertheless, both

ideas and thoughts follow an order, can be structured and demand study. Indeed, they

motivate the Universal Characteristic.

How can we speak of “them” if they do not exist? Language and speech are nothing but

vehicles for representing thought, and a thought may be about “any nature or form whatever”,

thing, notion or idea. In any case, all we are doing is progressively bringing out of our

memory in clearer and more distinct form ideas that have always been with us. They would

have to have been, since our soul – like all monads – perceives all other monads and therefore

has knowledge of the entire universe. However, the perception is unclear and indistinct.

A mind/soul can represent to itself a thing that is not real. However, the universe was (in the

design phase) constructed in God’s mind. The perfect universe (of the many so conceived by

God’s mind) was willed into existence. That universe is in conformity with ideas, which only

means that the universe is consistent with itself and is good, i.e. is a reflection of God himself.

So by understanding the universe we understand God. The universe, in turn, manifests every

possible good. Ideas are simply mental constructs for understanding the universe and hence

the good (God) as well as vice-versa, i.e. ideas are mental constructs for understanding the

good (God) and hence the universe.613

There is a paradox in that what is most evanescent offers the greatest power, perhaps the only

power, to affect the physical universe. Three concepts are considered: ideas, which do not

exist; souls, which are immaterial; and perceptions within souls which are merely mental

impressions. Ideas are not even real and so are “less” material than the immateriality of souls

and are also less material than the images which comprise the perceptions within souls. Yet it

is from ideas that souls derive their power. In particular, it is by the distinctness with which

ideas are perceived that their power is measured. This is only because a thought can only

correspond to physical reality to the extent that it represents an idea. Riemann formulated a

theory of thought that appears to be a maturation and consolidation of the mechanism and

613 Hermes Trismegistus identifies God with and as good, whereas Leibniz identifies God with that than which

there is no greater. Nicolaus of Cusa identifies God with “Absolute Maximality” or that than which there is

no greater, meaning the infinite. De Docta Ignorantia Book I Chapter 2 §5 in Hopkins, J. (trans.) Nicolaus of

Cusa De Docta Ignorantia The Arthur J. Banning Press, Minneapolis 3rd ed. 1988, p.6

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role of Leibniz’s “perceptions”. Riemann used the term Geistesmassen which can be

translated as thought masses, spirit masses or mind masses.614 The term “mass” could

mislead. Riemann’s emphasis is on the fact that Geistesmassen are the locus of activity of

intelligent souls. Mixing in Leibniz’s terminology, when a thought mass is sufficiently clear

and distinct, it can give rise to action by the corresponding body monad. The closer the

thought mass is to representing an idea, the more effective the consequences of its guidance of

the corresponding body monad in the physical world will be. For example, if a scientific

concept is incorrect, then it is not an idea and physical structures or machines will not work if

their design is based on that concept. If a scientific concept is correct, even if only within a

particular domain, i.e. it is closer to being an idea, then it can be used for new engineering

possibilities.

When monad X distinctly and unconfusedly perceives the indistinct perceptions in monad Y,

are the perceptions of monad X ideas? Yes, because such distinct perception would

understand the long chains of causes and implications of the indistinct perceptions of Y. Such

perceptions by X give it indirect power over Y because it understands Y.

Humankind as a subject of physical science

Due to the relationship of God to Man, since God is the starting point for a priori scientific

thought, it is necessary to understand Man in the a priori fashion too. Indeed, just as it is only

possible to theorize about God in the a priori fashion and possibly have some conclusions

thereby reached confirmed or denied by experiment or mathematics, the same is true of Man.

Even an Atheist, to whom the concepts of divinity of Man and God’s relationship to Man are

meaningless if not offensive, the fact that Man has a conscious creative power not found

elsewhere in nature begs special attention.

The difference between our ideas and our brand of creation versus that of nature (i.e. what

God chooses to allow, aside from humans) is critical to our understanding the character of

intellection beyond nature but below God’s. God made nature, but could do much more;

instead, God wants humans to extend nature. This can only be to allow humans the

opportunity to improve themselves, since God could have done and could do anything that

humans might ever do. The upwards development of humans is part of the process of

perfecting the universe. A teacher gives its pupils opportunities to create, and does not jump in

and take over out of impatience. The teacher’s task is for each student to successfully create

autonomously.

At the same time, there is nothing in nature which could do what Man can do. Only a self-

conscious entity such as Man can undertake creation of the kind that Man can. Thus, Man is

God’s natural instrument for that very kind of creation. Necessary to the self-consciousness

that must go hand-in-hand with the divine creativity that Man has is political conflict,

614 Riemann, B. Gesammelte mathematische Werke, wissenschaftlicher Nachlass und Nachträge “Collected

mathematical works, scientific deductions and supplements” , Springer-Verlag, Berlin Heidelberg New York

1990. In particular, see I. Zur Psychologie und Metaphysik “I. On psychology and metaphysics” pp.541-2 of

Fragmente philosophischen Inhalts “Fragments philosophical content” for a concise introduction.

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oligarchism, etc. Because we are self-conscious, we will naturally have trouble understanding

our own nature or character, just as it took thousands of years to discover various natural

physical laws. On the other hand, Man is not God’s instrument. Man is God’s project. God

wants Man to succeed in autonomously developing or evolving the physical universe upwards

but, again, for the sake of Man not the universe per se.

“Ideas” (in the strict monadological sense) about humankind

Ideas, which are often presented as laws, about ourselves and our creative capability cannot

be studied empirically in the way that some physical phenomena can be studied using

physical experiment. As yet, we have no systematic empirical way of discovering such laws.

Thus, we have been limited to the a priori or, at least, purely intellectual method.

Sensory perception and concepts that are able to be visualised clearly in a way that is akin to a

sensory perception but held in the mind are the locus or raw materials of the Empiricist mode

of thought and investigation. These loci are not a very effective way of discovering such laws

because there is little in the external world that is indicative of the potential, nature or role of

Man. First of all, humanity largely lives in the realm of final causes which, by definition, does

not permit the use of empirics. Second, manifestations of humankind in the realm of efficient

causes generally require the discovery to be made first and then be implemented into human

society and human law and government. It may then take decades or centuries for the results

to manifest themselves which can then be pointed to as proof of whatever the presumption

about human nature had been. Thus, only the a priori method is of significant value and this is

based purely on thought.

There have been many political experiments in history. There are libraries of books on the

results of those experiments. Arguably, many political systems resulted in disaster because the

a priori work had not been done or had flaws: such flaws would be regarded as moral flaws.

As mentioned above under the heading “The problem of evil”, moral ideas are as much a part

of the domain of discoverable truths as any “physical scientific” question of, say, gravity or

air pressure. The point is the moral truths are physical scientific, and the nature of Man is a

physical scientific question because Man is a force for change in the universe. Man is a

particularly interesting question of this kind because Man intentionally effects physical

change in a way that is bounded but is not restricted, as such, by the physical laws that govern

inanimate matter or the laws that govern living biological matter.

Historically, very few people think. Thus, progress is slow. Ideas about human nature impact

human institutions which means that oligarchical or control structures are threatened. This

discourages mentation on such ideas, further slowing progress. People generally take their

signals from empirics and can thus be corralled relatively easily, discouraging or preventing

mentation on ideas about our self-conscious selves and even more strongly suspending their

promulgation, implementation or even serious consideration.

Thus, progress in the realm of final causes – which is the immaterial or soul domain – is far

slower than our progressive understanding of “efficient causes”. Yet the realm of final causes

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is more powerful or, at least, enormously more influential in Man’s impact on the universe.

Yet, it is certain that such ideas can be reasoned about. Plato’s The Republic is a starting point

for a demonstration of how. Leibniz explains that it is so in New Essays and provides further

guidance as to the “how” throughout his writings.615

Foundations of a programme for discovery

We now have established sufficient background to be able to resolve and draw together a

number of apparently conflicting threads in Leibniz’s and Nicolaus of Cusa’s conceptions of

the role of ideas and possibilities for scientific discovery.

Leibniz is unambiguous that ideas are not real, in that they have no metaphysical/ontological

existence and certainly no physical existence. However, ideas are a standard by which

perfection is measured (at least, sometimes) and, therefore, define components of - and

totalities within - the physical universe. To Leibniz, there is nothing “more perfect” about a

geometrical square than a roughly cut square paver in the physical world, because the

physical world is (a) real and (b) the best of all possible worlds. The roughness of the paver is

necessary, is a part of its beauty and that beauty includes its role in the totality of the universe,

and is a characteristic of the unfolding upshifting of the universe - and the people in it - to

betterment.

It seems that there is an independent concept of “the Best”. Or is it simply God-defined? If

“Ideas” are given to us by the best possible universe, they are given to us by “the Best” which

is itself an idea. Because we do not know what ideas are - or which concepts are ideas - unless

we see them in all the complexity of the universe, we need to define them (and the Best) by

the universe. God does not care about a perfect square’s ideality. He cares about how to get

the best possible universe, and a perfect square may or may not be part of that.

This may be why Riemann suggested that physics (as a study of the actual, physical universe)

comes first and mathematics second. It often happens that we find ideas in this Best universe.

Thus, it is useful for us to investigate ideas (or what we in our limited understanding think of

or perceive as ideas) so we have advanced ones “on the shelf” for when our studies in physics

need them. After all, the principle of plenitude says that everything that is possible - is.616

Ultimately, we do not know whether what we think is an idea is an idea until it has been tested

in the universe or by checking against the universe (i.e. by experiment). Theoretically, we

could know without “testing” but that would require us to - like God - hold the entire universe

(and all of its possible unfoldings) in our mind in a single thought. Similarly, as it is hard to

the degree just described which concepts are ideas, it is just as hard (perhaps by orders of

magnitude) to know what “the Best” is. Again, the complexity is such that it may be that it

can only be known by holding the entire universe in the mind at once. No doubt, however,

there are principles for the discovery of which we need to start forming hypotheses, as

615 Langley, A.G. (ed.) Leibniz, G.W. New Essays Concerning Human Understanding Open Court Publishing,

Illinois 1949, p.95ff 616 As does Hermes Trismegistus. Corpus Hermeticum II §13 in Copenhaver, B.P. Hermetica Cambridge

University Press 1992, p.11

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Leibniz has done. They ought to be simply. Leibniz believed that the hypotheses can be

formed or worked out using his Universal Characteristic. Thus, it is possible that it is not

necessary to have to be able to hold the entire universe and all its possible unfoldings in our

mind at once in a single thought in order to be able to determine what the Ideas are or even

what the Best is.

We are still left with the question, (a) does the Best Universe define the Ideas (which includes

the Best), or (b) is it vice-versa? Because, from De Docta Ignorantia, we will never equal

God, assuming (a) is more correct. However, we necessarily chip away with (b). The

Universal Characteristic would provide a series of leaps in the pursuit of (b). The Universal

Characteristic itself would necessarily have limitations or a “ceiling” per De Docta

Ignorantia, and so would each success incarnation or version of the Universal Characteristic.

We see in all this how tightly woven science associated with experience of the universe as it

is, (a), is with a priori thought and the methods of Reason which include development of the

Universal Characteristic, (b).

Conclusion

As a result of their perceptions, appetitions and capacity for rational thought, human and other

souls make decisions that impact the physical universe. God plays an intermediating role, as

shown in Figure 7. Thus, the consideration of passive matter alone cannot give a complete –

and probably not even close to correct – understanding of the universe. The domain of physics

needs to be expanded to include the incorporeal, since the incorporeal control the corporeal,

as well as to include the connection between the two since that is the only way it is possible to

understand how the incorporeal controls the corporeal. More work is needed to understand the

pre-established harmony, which is in the middle part of Figure 7, and on how thoughts (i.e.

the internal activities of soul monads) can attain more closely to ideas which is the left node

in Figure 7.

Two open questions present themselves. The first relates to the pre-established harmony.

Is it possible to define the correspondence between the soul or thoughts and the corresponding

body monads as a mathematical relation? Leibniz argues that God links thoughts with actions

in the best possible way. This leads us to the second. Can we discover a general definition for

“the Best” perhaps for improvement over time? Since the universe corresponds with “the

Best” possible, which is not always the same as what we think of as ideals or mathematicals,

can we formulate an overarching criterion, or criteria, for the Best without having to hold the

universe and all of its possible unfoldings in our mind in a single thought like God can? We

know from Kepler that the reality of the universe is harmonious, beautiful and brilliant, but

those do not serve as working criteria nor were they intended to.

The ongoing re-creation of the universe as directed by the thoughts of soul monads

necessitates a design which places thinking soul monads at the top of the universe. The

Creator has given soul monads the prerogative to create if they are able to be active (i.e. to

think rationally, in the strict Leibnizian sense) and choose to be. Indeed, even if soul monads

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choose dullardism, they are by the nature of the role allotted them still the ones to which

God’s attention turns in the unfolding of creation via the pre-established harmony. Thus,

Leibniz vindicates the Renaissance view of Man.

Figure 7(a): pre-established harmony between a body and soul pair of monad counterparts

Figure 7(b): pre-established harmony at the collective level of all reality between all that is

incorporeal (all active matter) and all that is corporeal (all passive or physical matter)

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Chapter 9: A priorism in science

Introduction

Leibniz sought to re-orient and enhance the burgeoning program of experimental science.

Leibniz wanted a primary emphasis on structured thought with experiment playing a

supporting role to the reasoning process. Leibniz saw that in his lifetime, there was a risk that

experiment would become primary with reasoning relegated to a secondary and supporting

role. Indeed, some writers such as Sarpi and Newton as discussed above sought to exclude

reason, and substitute experimental evidence or the testimony of the senses for the capabilities

of the mind.

Wiener notes an oscillation in Leibniz’s writings “between his a priori system of irreducible

real definitions and the experimental aspect of his program”.617 Leibniz certainly gave

attention to experimentation, even writing that he is in the habit of writing out a catalogue of

experiments to be done when he examines some matter of physics. He will ensure that the list

includes all experiments needed to find the cause of what is in question “through

demonstration and not through Hypothesis”.618 This shows that Leibniz was not an a priori

fanatic, but – as in all other things – a pragmatist.

Nonetheless, a discussion of the importance of a priorism in science would be incomplete

without giving examples of its use. Are there examples to which we can point and say that a

priori thought was critical to a discovery or a process of discovery whose results had enduring

value? We will discuss three examples: Leibniz’s work in creating the calculus, the discovery

of non-Euclidean geometry and Kepler’s work in Mysterium Cosmographicum.

A priori thought is often equated with seeking to understand the mind of the Creator with

observed physical phenomena playing the positive role of acting as a challenge influencing

the direction of this quest by introducing new questions or challenging existing answers.619

Therefore, the chapter ends with a brief section on some contemporary references to the mind

of God which are not in agreement with the Leibnizian a priori programme.

The obvious challenge is: name one discovery that was made by observation alone.

Discoveries are rarely made by pure observation and, when they are, much more hard work

that requires thought as well as observation is required to give meaning to the initial

interesting observation. Contradictions might be found between observations. Problems in

accuracy and consistency are found with observations. Critical information is found through

observation, but observation does not give new understanding. Typically, observations while

sometimes answering questions usually lead to more questions. Eratosthenes might have

hypothesized the shape of the earth from an observation. But the same observation had been

617 Wiener, p.xxvi 618 Letter to Berthey 1677, Ibid., p.xxiv 619 This is to borrow the words of Meli but to use them in a different context. Meli, D.B. Equivalence and

Priority: Newton versus Leibniz Clarendon Press, Oxford 1993, p.19

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made by others many times before without Eratosthenes’ hypothesis springing to their mind.

Eratosthenes might then have used observations to determine the radius of the earth, and thus

answer a question, but in his mind he had already formed a view as a result of observations.

Differences in the lengths of shadows at the same time of day exposed a contradiction which

Eratosthenes attempted to resolve by forming an hypothesis. Once he had done so, he was

able to ask a question which could then be answered by further observation, which was really

interpretation of experience through the lense of his understanding/hypothesis.

The calculus’ development from Archimedes to Barrow to Leibniz involved little or no

practical experimentation. The same can be said of the development of Euclidean and non-

Euclidean geometry. However, the discoverers were affected by thinking that resulted from

experience. For example, Archimedes and Leibniz were engaged in experimentation and

thinking related to physics, which must have had some impact on their treatment of the

infinitesimal.

Clearly, Kepler’s development of planetary motion and gravity was partly guided and partly

set off in new directions by empirical observation, as was Copernicus’ work. Their

development of ideas relating to properties of the universe may not have been made had it not

been for the development of precision in astronomical observations in their time. To have

discerned those ideas from principles pertaining to how God works (“that the universe could

not be other/better than it is”) would have been too much of a leap for Copernicus’ and

Kepler’s time, and perhaps even for today. This does not mean that Kepler’s discoveries

would, in principle, have been impossible without the telescope. Leibniz’s point is that the

indistinctness and confusedness of our reasoning leads to erroneous theory, and generally

prevents us from learning about the universe without at least some empirical information

versus by way of pure thought. Leibniz agrees that more precise observations can reveal

errors in theory. Kepler and Copernicus’s striving to correct the disagreements between the

Ptolemaic theory and increasingly precise astronomical observations is nothing but an

example of new empirical information revealing the “confusedness and indistinctness” of our

mental conceptions and reasoning.

Indeed, pure thought even with human imperfection and our general dependence on

observation maintains a power that observation cannot have. Franklin’s paper, on two

perspectives of Leibnizian optimism explains how we can, and often do, work out

mathematically – i.e. through pure thought – what is not possible and thus what things we

could never observe because they could never occur.620 The paper notes that proving what

must be is a long way from proving what cannot be. Nonetheless, Franklin argues that pure

thought can be a very powerful thing and can provide results that no experiment ever could: a

truth that holds always and everywhere.

In the three domains of discovery considered here, a priori thinking dominated and was

probably decisive. Most domains of discovery bear fruit over several generations of thinkers

who build on one another, so a complete argument that a discovery resulted from a priori

620 Franklin, J. “Two caricatures II: Leibniz’s best world” International Journal for the Philosophy of Religion 52

(2002), 45-56, accessed at http://web.maths.unsw.edu.au/~jim/caric2.pdf

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thinking requires consideration of those thinkers over multiple generations and centuries. We

do not have the space for a full study of that kind.

Example 1: The infinitesimal and the calculus

Leibniz’s development of the calculus involved much more than the infinitesimal though the

infinitesimal is a core concept. However, the great ancillary work did not involve empirical

observation though it did involve mental images and diagrams of curves to help clarify ideas.

Bagni says that the development of the calculus often assumed “an aprioristic platonic

epistemological perspective”.621

This perspective was not limited to curves in the abstract, nor did it even begin with abstract

curves. In 1675, Leibniz generalized the calculation of centre of gravity of a figure, and the

calculation of the moment of a figure about any given line.622 Leibniz acknowledges that

Cavalieri pioneered the use of the infinitesimal idea for moments.623 Child points out that

Cavalieri used the phrase “incrementum difforme gravitas” to “connote a gradual increase

that follows a definite law” (emphasis in Child).624 In 1679 in a Letter to Tschirnaus, Leibniz

wrote, “Huygens, who thought me a better geometer than I was, gave me to read the letters of

Pascal, published under the name of Dettonville; and from these I gathered the method of

indivisibles and centres of gravity, that is to say the well-known methods of Cavalieri and

Guldinus.” 625 In July 1676, when investigating the “inverse method of tangents” (quadrature)

Leibniz wrote, “There is indeed another method that is more general and a priori, namely, by

the intersection of two tangents, which should always intersect between the two points at

which they touch the curve, as near one another as you can imagine”.626

621 Bagni, G.T. 94–103 “Exhaustion argument and limit concept in the History of Mathematics: educational

reflections” In Furinghetti, F. Kaiser, S. & Vretblad, A. (Eds.), Proceedings of HPM–2004, History and

Pedagogy of Mathematics, Uppsala July 12–17, 2004, at p.4 622 Leibniz, G. W. “Analytical quadrature by means of centers of gravity” in Child, J. M. (ed. and trans.) The

early mathematical manuscripts of Leibniz; tr. from the Latin texts by Carl Immanuel Gerhardt with critical

and historical notes by J. M. Child The Open Court Publishing Company 1920, republished by the University

of Michigan Library, p.66 623 “In 1629, Cavalieri, a Jesuati – an adherent to the Rule of St. Augustine – was appointed to the chair in

mathematics at the University of Bologna, a post he occupied until his death, largely through the

recommendation of Galileo, who proclaimed him the foremost Italian mathematician of the day. His

Geometria indivisibilibus contains the first systematic exposition, as it pertains to the principles of

summation, of what we now know as the calculus. He accomplished this by employing the concept of

‘indivisibles,’ or ‘infinitesimals,’ which served the same purpose as ‘the method of exhaustions’ employed by

Archimedes and other Greek mathematicians. In principle these approaches were the same but the system of

notation for indivisibles was much more concise and convenient.” Accessed at

http://www.brown.edu/Facilities/University_Library/exhibits/math/textfr.html#bon.html 11 May 2011. The

original text referred to is Geometria indivisibilibus continuorum nova quadam ratione promota ...

Typographia de Duciis, Bologna 1635 624 Child, J.M. (ed. and trans.) The early mathematical manuscripts of Leibniz; tr. from the Latin texts published

by Carl Immanuel Gerhardt with critical and historical notes Open Court Publishing Company, Chicago and

London, 1920 reprinted by University of Michigan Library, pp.208-9 n.25 625 Ibid., p.215. Also see further quotes at p.215 n.36. 626 Ibid., p.119

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Leibniz’s principle of continuity was based on his conception of how God thinks, via the

principle of sufficient reason which is a consequence of the best of all possible worlds

principle. Of course, the infinitesimal is a corollary of continuity. We do not know whether the

mathematical conception of continuity or the metaphysical principle of continuity came first,

but it is difficult to believe that one did not influence the other or perhaps the influence

worked in both directions. Yet, Cusa understood that, “As the mind considers it, the

continuum is divided into what is always further divisible and the number mounts to infinity.

But in actually dividing a line, one comes to a part that is actually indivisible. It is this I call

the atomic unit.” Yet Cusa knew that the atomic unit is “nothing” for he quoted Boethius

saying that, “If you add one point to another, you effect no more than if you join nothing to

nothing” and then wrote “if you connect the ends of two lines, you do make a longer line, but

the point of connection constitutes no length at all”. The emphasis here is on how “the mind

considers it”.627 It is on this intellectual artifice that the infinitesimal is based. Katz and Sherry

argue that the artifice of the infinitesimal is not fatal to the well-foundedness of the calculus.

Indeed, they say that the artifice is testament to the forwardness of Leibniz’s thinking, by

saying, “Leibniz’s was a remarkably modern insight that mathematical expressions need not

have a referent, empirical or otherwise, in order to be meaningful.”628

The presumption that continuity has atomic components – which are metaphysical only – with

which humans can calculate is the stride that Leibniz takes with his calculus. Indeed, the ratio

Δy/Δx approaches a ratio of atomic lengths which is called dy/dx. Had Cusa not brought the

idea of the infinitesimal out into the open, and discussed and analysed it, future generations of

thinkers might not have had the confidence to use the “atomic unit” as Leibniz did. Without

Leibniz’s conception of the infinitesimal, there would have been no Leibnizian calculus.

Further, Cusa’s analogy of the quadrature of the circle is so central to Leibniz’s work that

Grosholtz refers to the “infinite-sided polygon” perspective of the circle (for which Cusa is

famous) as “Leibniz’s infinite-sided polygon”.629

Leibniz’s a priori progress into the infinitely small allowed him to develop a method of

general applicability. Of course, thinkers before Leibniz had ventured into the infinitely small.

Child tells us that Leibniz’s sole introduction was the infinitely small division between

ordinates in the method of Cavalieri c.1672.630 From there, Leibniz considered the infinitely

small triangle which he called the Characteristic Triangle. (Note the synonymous terminology

with the sought-after Universal Characteristic which Leibniz believed could be found as the

basis for a general method to solve any problem.) Leibniz knew that this triangle was

“indefinite” and so it was not possible to perform calculations on it directly. However, “yet he

perceived that it was always possible to find definite triangles similar to it.”631 Incidentally,

the use of of dy/dx predominantly in reference to the Characteristic Triangle is one reason

627 Miller, C.L. (trans. and intro.) Nicolaus of Cusa Idiota de Mente Abaris Books, New York 1979, pp.71-73 628 Katz, M. and Sherry, D. “Leibniz’s Infinitesimals: Their Fictionality, Their Modern Implementations, and

Their Foes from Berkeley to Russell and Beyond” Erkenntnis Springer 2012 Vol. 77 629 Grosholtz, E. “Was Leibniz a Mathematical Revolutionary?” pp.126, 133 630 Child, J.M. (ed. and trans.) The early mathematical manuscripts of Leibniz; tr. from the Latin texts published

by Carl Immanuel Gerhardt with critical and historical notes Open Court Publishing Company, Chicago and

London, 1920 reprinted by University of Michigan Library, p.38 631 Ibid., p.39

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why Richard Brown considers Leibniz’s calculus as fundamentally different from Newton’s

fluxions which assists Leibniz’s cause in the calculus priority debate.632

We have just described a priori thought that is removed from observation by two degrees of

abstraction. First of all, the definite triangles on which Leibniz performs calculations are

themselves creations of the mind. Second, he uses those calculations to make inferences about

the indefinite triangle about which he can presume to know very little directly.

The calculus is not necessarily complete. New understanding of the infinitesimal domain

might be reached in the future causing the Leibnizian calculus to give way to a better and

more powerful calculus. For example, there may be a time in the future when we find certain

qualities of the indefinite triangle which need not be regarded as true or which are provably

false in the infinitesimal domain. That is, just because an indefinite triangle is similar to a

definite one, why must they necessarily share certain qualities? The edifice on which the

calculus is built may collapse to give way to a more general calculus.

Leibniz reached a certain point in his development of the calculus when the calculations were

entirely algebraic. This in itself was an achievement. However, the differentiability or

integrability of a curve then depended on the form of its algebraic equation. As is standard for

mathematicians today but was not in the 17th Century, Leibniz considered equations of

“infinite prolixity”633 and systematically showed that such equations did not pose a problem

for his calculus.

Leibniz proceeded to integrate the powers of x and stopped at x3 for, as Weissenborn said, “his

soul is in the throes of creation”.634 He proceeds to derive the method of the integration of a

square, such as f(x)2 and thence a particular case of integration by parts xf(x).635 Shortly

thereafter, Leibniz notes that integration has the effect of raising the dimension of the thing

integrated regardless of how large the dimension might be.636 For example, integrating a line

over an interval produces a 2-dimensional area, integrating an area through some revolution

produces a 3-dimensional volume, and so on.

632 Brown, R. C. Leibniz unpublished, Chapter 11 “Epilogue”, p.177. For Leibniz, dy/dx “is simply a device to

calculate the subtangent t from the equation dy/dx = y/t.” However, “Had Leibniz been influenced by

Newton” we would expect Leibniz to have treated dy/dx as an independent object, function or rate of

change.” We have avoided the priority debate and it remains beyond the scope of this thesis. However,

Leibniz knew that curves can be used to represent all manner of quantity such as distance, velocity, rate of

change itself, or any quantity one seeks to measure. So dy/dx might have represented many quantities and

Leibniz was certainly aware that it was a rate of change. By finding the subtangent, Leibniz knew that he was

opening up the facility for calculation with any quantity one happened to be analyzing in the form of the

curve to which one sought the subtangent. He was aware of the generality of mathematics and he knew that

the tangent represented an instantaneous rate of change. However, it is true that Leibniz’s focus on dy/dx was

due to its role with respect to the Characteristic Triangle which was so important to the development of his

method. 633 Child, J.M. (ed. and trans.) The early mathematical manuscripts of Leibniz; tr. from the Latin texts published

by Carl Immanuel Gerhardt with critical and historical notes Open Court Publishing Company, Chicago and

London, 1920 reprinted by University of Michigan Library, p.77 634 Ibid., p.75 635 Ibid., p.80 636 Ibid., p.80

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In 1675, Leibniz completes working which he believes will enable him to find the quadrature

(integral) of any conic. Child notes that the effort comes to nought and, even if it had not, he

would have obtained a large quadratic whose roots would have been too complicated to

use.637 Nonetheless, in the process, Leibniz exhibits a number of qualities of a priori

reasoning.638

Arithmetical progression

Leibniz considers how y changes when x changes in arithmetical progression. This is an

“artifice” whereby he draws out details on the expression for the curve for the following

purpose of eliminating terms.

Eliminating terms

Given that Leibniz has established himself in purely algebraic manipulation, he seeks

“artifices” which may simplify the working. Where there are more equations than there are

unknowns, solution is problematic. However, by taking a variable to be in arithmetical

progression, he is able to create additional equations and thus eliminate an undesired

unknown.

Moments

By employing an argument that is partly geometrical and partly algebraic, Leibniz proceeds

with an alternate route under the heading of “moments”. That is, he is able to produce two

expressions for the same thing with one slightly different due to its being resolved into two

parts with the one being infinitely small compared with the other.639

We can understand why Cauchy complained that Leibniz’s infinitesimal lacks precision.640

This is because Leibniz uses “artifices” to trick his formulae into simplification so as to “lay

bare” their secrets.

In addressing claims that indefinable real numbers cannot exist because they are not

denumerable and cannot be written down in decimal format, Franklin and Newstead argued

that the fact that we cannot see something directly does not mean that it is not there. Leibniz

has an unusual variation on this problem with his own critics. He took the view that if we

have forced something out into the open that we did not know to be there, we can still use it

even if we do not understand why it is there.

Further, the more we appreciate the “precision” which the limit conception (or δ/ε definition)

of the infinitesimal brings, the more it seems to be at the cost of distracting or misdirecting us

from the more exciting – and, probably, ultimately more fruitful – hunt for what Leibniz was

637 Ibid., pp.97-103 638 Ibid., pp.93-103 639 Ibid., p.98 and in footnote 34 on the same page, Child notes the advance in Leibniz’s thinking exhibited by

Leibniz’s use of the idea that one quantity is “infinitely small compared with” another allowing the former to

be discarded. 640 This is referred to by Boyer many times uncritically. See Boyer, C. The History of the Calculus and its

Conceptual Development Dover Publications: New York 1949

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actually taming. There seems to be a wild beast (or orchid) in the domain of ideas of which

Leibniz had only begun to get a smell.

Leibniz defended and encouraged the use of “artifice” to permit calculation with the

continuous. For Leibniz, it was not necessary that his conception of the infinitesimal actually

exists because it is a useful tool. Why would he so water it down, by disconnecting it from

how he regarded the universe to actually be? We suggest three possible reasons:

(a) He did not want society to be denied the benefit of his calculus as a pragmatic aid to

human development. Further, he did not think that the Republic of Letters would reach

agreement on his metaphysical arguments on continuity any time soon.

(b) He knew that he was expressing a property of metaphysical reality in precise terms,

and was not so arrogant as to think that such a profound idea could not be expressed

with greater fidelity than he had expressed it. In the meantime, he hoped his calculus

to nonetheless be able to enable a great contribution to human development.

(c) He intended his infinitesimal calculus to be a tool of engineers and other “men of

action” who had no interest in metaphysics or theology.

Beyond Leibniz, it is by the a priori method that Riemann qualifies the validity of Leibniz’s

infinitesimal triangles. Over II §2 and III §1 Riemann makes it clear that infinitesimal

triangles are only applicable in a space of curvature zero and in which the angle sum of a

triangle is two right angles.641

Example 2: The Fifth Postulate and Non-Euclidean geometry

The arguments surrounding Euclid’s Fifth Postulate and tacit assumptions made by Euclid are

rich with a priori reasoning with far-reaching ramifications for geometry and for human

conceptions of the structure of the physical universe.

Euclid’s “postulates” were in the original Greek merely “requests”.642 Torretti says that Euclid

did not regard his “requests” as self-evident. Nonetheless, Keyser wrote that Euclid’s Fifth

Postulate (as it is called) was “perhaps the most famous single utterance in the history of

science”.643 Euclid’s The Elements is often regarded as a triumph of the ideal, or a testament

to what the mind can create through pure logic beginning with some basic postulates. Thus,

Euclidean geometry might suffice as a persuasive example of the power of a priori thought. It

is perhaps not surprising that it should be found wanting by a priori methods. Nonetheless,

641 Spivak, M. A Comprehensive Introduction to Differential Geometry Vol. 2 Publish or Perish, Inc., Houston,

1999 p.160 642 Torretti, R. “Nineteenth Century Geometry” in Stanford Encyclopedia of Philosophy 1999 revised 2010.

Accessed at http://plato.stanford.edu/entries/geometry-19th/ on 18 March 2011. Indeed, the word Euclid uses

is “Αίτήματα” (pronounced aiteemata) from Mourmouras, D.E. (ed.) Euclid The Elements accessed at

http://www.physics.ntua.gr/~mourmouras/euclid/book1/elements1.html 19 March 2011 which Google

translates as “requests”. The Greek Lexicon translates “aίτημα” as a request or demand. (An Intermediate

Greek-English Lexicon: founded upon the Seventh Edition of Liddell and Scott’s Greek-English Lexicon,

Oxford University Press) 643 Keyser, C. J. Mathematical philosophy : a study of fate and freedom E. P. Dutton & Co., New York 1922

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because Euclidean geometry has been so important, we regard the devising of non-Euclidean

geometry as a legitimate example of a priori mathematical and – as we shall see when we get

to Riemann – scientific thought. The consequences of non-Euclidean geometry are more

significant for physics than its own discovery, because non-Euclidean geometry allows

physics to be done with mathematics.

The Fifth Postulate was queried for many centuries before its true nature was found. For

example, in the 13th Century, Nasir al-Din (Eddin) al-Tusi, astronomer to Hulagu Khan

(brother of Kublai Khan and grandson of Genghis Khan) thought that it could be proven by

the first four postulates and therefore did not have to be included as a postulate.644,645 Boyer

and Merzbach write that al-Tusi was the last of the Arabaic precursors to non-Euclidean

geometry, that John Wallis published al-Tusi’s work in the 17th Century which was the starting

point for the work of the Jesuit Girolamo Saccheri in the early 18th Century.

Saccheri assumed that the two summit angles of a quadrilateral are less than 90 degrees and

tried to find a contradiction. Due to his preconception of that the two summit angles had to be

right angles, he “found” a contradiction with his initial assumption that the upper angles are

less than 90 degrees. This was published by Saccheri in a booklet entitled “Euclid Cleared of

Every Flaw”. Since Saccheri’s did not convince mathematicians, it enlivened interest in the

non-necessity of the fifth postulate even though this was not the conclusion reached by

Saccheri himself.646

A breakthrough came with Lobachevsky and Bolyai simultaneously and independently.

Lobachevsky motivated his Pangeometry by the fact that the consequences of the Fifth

Postulate “which, although they appear simple, nevertheless, appear arbitrary, and

consequently, inadmissible.”647 He begins by defining a line by the locus of intersection of

equal circles centred at two fixed points, and a plane by the locus of intersection of equal

spheres centred at two fixed points.648

Lobachevsky makes it clear that he regards his new non-Euclidean geometry, “Pangeometry”,

as an a priori construction which is “a complete geometric doctrine”.649 It is of interest

because it provides “methods that are useful for the computation of various geometric

quantities.” He says that the idea that the angle sum of a triangle is constant is “not a

necessary consequence of our notions of space” and then says “only experience can confirm

the truth [or otherwise] of this assumption”. So from something that is inadmissible because it

appears arbitrary, Lobachevsky has made a prediction that if we examine real rectilinear

triangles – especially large ones – we will find that their angle sum varies.

644 Boyer, C.B., Merzbach, U.C. A History of Mathematics John Wiley and Sons 2011, Chapter 11 “The Islamic

Hegemony” 645 Mathematics Illuminated Geometries Beyond Euclid published by Annenberg Learner §8.3 Non-Euclidean

Geometry accessed at http://www.learner.org/courses/mathilluminated/units/8/textbook/03.php 4 June 2011 646 Ibid. 647 Lobachevsky, N.I., Papadopoulos, A. (trans.) Pangeometry, European Mathematical Society Zurich, 2010 p.3 648 Ibid., p.4 Papadopoulos notes that the definition of plane is akin to Leibniz’s: that surface which divides space

into two congruent parts. 649 Ibid., p.75

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Lobachevsky and Bolyai independently developed non-Euclidean geometry at almost the

same time. Riemann, working in the post-Fifth Postulate environment, distinguished

“unboundedness and infinite extent”650 which removes the necessity for infinitude of the line

and creates circumstances wherein the Fifth Postulate fails.651 Wolfe pointed out that Euclid

unconsciously assumed the infinitude of the line, which is a weak point of the Fifth Postulate,

in his proof of Proposition I.16.652 This is a case of the “‘hidden lemma’ or unacknowledged

assumption” referred to by Richard Brown, the uncovering of which is central to the

dialectical development of mathematics.653 Joyce points out that the first 15 propositions of

Book I of The Elements hold in elliptic geometry but not Proposition 16, saying “When a

‘straight line’ is extended, its ends eventually meet so that, topologically, it becomes a circle.

This is very different from Euclidean geometry since here the ends of a line never meet when

extended.”654 These considerations are all from thought alone.

It may be argued that the realm of geometry is by its nature the realm of thought. However,

geometry and physics are intertwined. Let us consider someone relatively recent, namely,

Riemann. Riemann found the basis of geometry as inseparable from physics when he said that

if space is a discrete manifold, then its metric relations can be discerned from within our own

understanding of that discrete manifoldness. If it is continuous, then we must understand the

binding forces which act upon it in order to understand its metric relations. These questions

are asked a priori and they provide the setting for the research programme to be undertaken in

understanding the universe.655

There may be critical experiments that can be designed to determine whether space is a

discrete or a continuous manifold. Such design would necessitate a priori investigation.

Indeed, the work already done with Lie groups and algebraic geometry in general can only be

regarded as a priori. Once we have determined whether space is a discrete or a continuous

manifold or some third possibility, then a priori speculations will need to begin anew. In the

end, we see that according to thinkers such as Riemann, physics not only can but must be

carried out just as a priori as can geometry. Physics since Riemann seems to have borne this

out, with most progress occurring in the mathematical domain punctuated by experimental

results, rather than vice-versa.

650 Riemann, B., Clifford, W.K. (trans.) “On the Hypotheses which lie at the Bases of Geometry” Nature, 8

(1873), pp.14-17, 36-37. Accessed at http://www.mat.ub.es/EMIS/classics/Riemann/index.html on 15 March

2011 and in Spivak, M. A Comrehensive Introduction to Differential Geometry Vol. 2 Publish or Perish, Inc.,

Houston, 1999 p.160 651 Wolfe, H.E. Non-Euclidean Geometry, Holt, Rinehart and Winston 1945, p.8 652 Ibid., p.6 653 Brown, R. C. “The Deconstruction of Mathematics” in Brown, R. C. Are Science and Mathematics Socially

Constructed? A Mathematician Encounters Postmodern Interpretations of Science World Scientific

Publishing Co. Singapore 2009, p.165 654 Joyce, D.E. Euclid’s Elements accessed at http://aleph0.clarku.edu/~djoyce/java/elements/bookI/propI16.html

on 27 Apr 2011 655 Riemann, B., Clifford, W.K. (trans.) “On the Hypotheses which lie at the Bases of Geometry” Nature, 8

(1873), pp.14-17, 36-37. Accessed at http://www.mat.ub.es/EMIS/classics/Riemann/index.html on 15 March

2011 and in Spivak, M. A Comrehensive Introduction to Differential Geometry Vol. 2 Publish or Perish, Inc.,

Houston, 1999 p.160

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Riemann identifies a domain of growing interest in which only a priori speculation can lead

to progress when he concludes in the fourth-last paragraph that, “it seems that the empirical

notions on which the metrical determinations of space are founded, the notion of a solid body

and of a ray of light, cease to be valid for the infinitely small.” Thus, he says, we are free to

suppose the metric relations of space in the infinitely small do not conform to the hypotheses

of geometry. Moreover, he says, we should suppose this as soon as it permits a simpler

explanation of phenomena, which is nothing but a criterion for the desirability of an a priori

speculation.656

Typical of the conclusion of a priori work in physics from Riemann’s view is the work of

Archytas from the 4th Century BCE.657,658 The physical result of doubling the cube arose from

manipulating curves in a way that only the mind’s eye could conceive and which is not

subject to empirical observation (unless it has already been constructed deliberately).

Wolfe points out that intuition is not always reliable.659 Thus, Pasch and others introduced the

Postulates of Order which may seem to be obvious,660 but which do not always hold, and

which Euclid assumed in proving Proposition I.21. It would seem that such tacit assumptions

of Euclid would be among the difficulties that Riemann referred to when he said “the

empirical notions on which the metrical determinations of space are founded … cease to be

valid for the infinitely small.” Leibniz would agree that some geometry that holds for the

infinitely small, for there must be structure at all levels, but such a geometry is not something

that would correspond to intuitive conceptions resulting from our day-to-day experience.

We know what Leibniz says about continuity: the principle of sufficient reason demands

continuity always in the universe, or no discontinuities. Dedekind provides what is generally

regarded as a satisfactory definition of continuity, but questions whether it holds even in

regard to an arbitrary straight line. He says that he cannot prove it and nor can it be proved.661

Dedekind’s postulate of continuity is that if all points of a straight line fall into two classes,

such that every point of the first class lies to the left of every point in the second class, then

there is one and only one point which produces this division of the line into two classes (or

this severing of the line into two portions).662 For example, one can imagine singularities in

656 Riemann, B., Clifford, W.K. (trans.) “On the Hypotheses which lie at the Bases of Geometry” Nature, 8

(1873) pp.14-17, 36-37. Accessed at http://www.mat.ub.es/EMIS/classics/Riemann/index.html on 15 March

2011 and in Spivak, M. A Comrehensive Introduction to Differential Geometry Vol. 2 Publish or Perish, Inc.,

Houston, 1999 p.160 657 Huffman, C. “Archytas” first published 26 Jun 2003 with substantial revision 25 Jul 2007, accessed at

http://plato.stanford.edu/entries/archytas/ on 27 Apr 2011 658 Rivest, F. and Zafirov, S. “Duplication of the cube” undated, accessed at

http://www.cs.mcgill.ca/~cs507/projects/1998/zafiroff/ on 27 Apr 2011 where it is said of Archytas’ solution,

“it is not a construction in a plane but a bold construction in three dimensions, determining a certain point as

the intersection of three surfaces of revolution, (1) a right cone, (2) a cylinder, (3) a tore or anchor-ring with

inner diameter nil. The intersection of the two later surfaces gives (says Archytas) a certain curve (which is in

fact a curve of double curvature), and the point required is found as the point in which the cone meets this

curve.” 659 Wolfe, H.E. Non-Euclidean Geometry, Holt, Rinehart and Winston 1945, p.9 660 Ibid., p.13 661 Ibid., p.10 662 Ibid.

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the domain of the infinitesimal in which there is no concept of left and right, or in which one

actually has a single point which has nothing to its left and nothing to its right. This might not

be as fatal to geometry as it might seem, as Wolfe says that a large portion of Euclidean and

non-Euclidean geometry can be constructed without the principle of continuity.663 This

vindicates Riemann’s uncertainty as to whether space comprises a discrete or continuous

manifold.

Leibniz’s belief that the universe must be continuous due to the principle of sufficient reason

was based on a priori reasoning regarding the nature of God. Suppose it was found that in the

realm of the infinitesimal – which is precisely where most discussions about continuity take

place – Dedekind’s continuity criterion fails. Such an outcome would be rich with paradox,

and could itself only be reached via a priori reasoning.

In discussing the foundations of mathematics it could be expected that a priori thought is

prominent. There is often an unavoidable segue into metaphysics, philosophy and even

theology to reach conclusions more sound from those which were held previously. Yet the

tools and presumptions of physicists, engineers and even policymakers emerge from these

foundations. Thus, the processes followed in exploring and concluding in the foundations of

science have vast real-world consequences over centuries of human history. Therefore, the

role and method of a priori thought is best explored, understood and refined rather than

ignored or cast aside in favour of putative pure empirical observation.

Example 3: Elliptical orbits in a heliocentric solar system

We can say that Kepler’s wiping the slate clean of epicycles upon epicycles (i) was – arguably

– justified by “common sense” (which is easy to say in retrospect) but (ii) was argued by

Kepler as more consistent with the simplicity and beauty of how he expects the Creator to

work. With Kepler’s theological background and clear orientation towards “understanding

how God thinks” as being the purpose of science, we would say that (ii) was more likely the

critical component which persuaded Kepler that there was something fundamentally wrong

with the epicycles approach and to “start again”. We doubt whether Kepler gave “common

sense” any importance at all.

This is diluted, certainly, by the fact that for Kepler to add even more epicycles to refine the

epicycles theory to fit the observations a posteriori was “getting a little bit ridiculous”.

However, we should hesitate to ascribe such vulgar late 20th Century tests on Kepler.

Kepler had to discard the concept that the perfectness of circles makes them a necessary

component of any theory of how the heavens move. We add that Kepler was not just

influenced by, but was an intellectual disciple of, Nicolaus of Cusa. Thus, he had to have been

aware that no human presumption of truth (such as that planets must move in circles) was

necessarily permanent. Rather, more is to be gained by exploring the domain of ignorance,

since that domain is inevitable and infinite. The question to ask would have been, “What if

663 Ibid., p.12

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we’re wrong about circles being necessary?” It is only by doing so that we may possibly come

up with a better theory. Cusa’s theory of docta ignorantia is entirely couched in the eternal

journey of the human soul towards the understanding that God has and towards an

understanding of God.

Kepler begins Chapter XI of Mysterium Cosmographicum, entitled “On the arrangement of

the solid, and the origin of the Zodiac”, with a paragraph both characteristically Platonic and

Pythagorean.664 He writes, “I have deduced the natural properties of the planets from

immaterial things and mathematical figures” and “I dare to investigate the origins of the

circles [of planetary orbits] from frankly imaginary cross sections.” Kepler then justifies the

view that God is a God that wills based on absolute reason, and nothing exists except by his

will. We will call this the Divine Architectonic Principle (“DAP”). For the scientist, the effect

of DAP is that we must limit our enquiry to the bounds of the inscrutable powers of the

Founding Wisdom. In long hand, this means that a scientist should work within the truth of

the fact that God gave effect to the mathematicals by using them as the foundation for the

architecture of the universe. Thereby, Kepler’s intention in Chapter XI is draw “likely

explanations” for the way universe is from “the quantities” meaning numbers and which, by

extension, means the Pythagorean corpus.

We must pair this with Kepler’s earlier footnote that God, as well as a tongue, has a finger. We

must not attribute meaning to God’s words that contradict the works of God’s finger as seen in

the physical universe.

Notwithstanding Kepler’s footnote 1 that the chapter could be omitted for it carries no weight,

in footnote 2, written apparently 25 years after he wrote Mysterium Cosmographicum, Kepler

says that working within the DAP has repaid him with interest over the last 25 years even

though in this instance (i.e., M.C. Chapter XI) it did not lead to a happy result. In particular,

he is talking about the chapter’s aim in demonstrating the arrangement of the zodiac and

numbers. He does not resile from his modus operandi and the intellectual criteria for a useful

argument that follow from DAP.

For the scientist, the Mathematicals are the cause of natural things and the reason for this is

that the Creator had the Mathematicals as archetypes with him from eternity in their simplest

divine state of abstraction even abstracted from numbers (when we consider numbers in their

material or empirical/intuitive aspect as quantities of things). It may be that it is with this

“shadow domain” that Leibniz was grappling, as outlined under the previous heading

“Infinitesimal”.

Kepler notes that Aristotle carped at the theory that the mathematicals are the cause of things.

Given that Aristotle denied the existence of the archetypes, it is not surprising that he denied

the existence of a Creator and decided that the universe was eternal.665 Kepler admits that the

archetypes would have possessed no force had God not had regard to them in the act of

664 Kepler, J. Duncan, A.M. (trans.) Mysterium Cosmographicum Abaris Books, Janus Series, Opal Publishing

1981 pp.123-125 665 But since ideas do not exist, then to Leibniz the archetypes do not exist, but they do subsist.

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Creation. This hearkens forward to Leibniz’s Theodicy (§184), where Leibniz writes, “It is

true that an atheist may be a geometrician: but if there were no God, geometry would have no

object. And without God, not only would there be nothing existent, but there would be

nothing possible.”666

It seems that Kepler is saying that we find the expression of God in the universe through (and,

perhaps, only through) the subsistence of the archetypes in the design/architecture of the

universe. This reminds of Leibniz’s architectonic conception of the universe.667

Ultimately, Kepler concludes that it must be that “splendid and plainly necessary causes” for

the eccentricities of the orbits of the planets nearer the sun:668

1. Can be derived from the harmonies as if from an archetype, and

2. Rest on the fact that God is the architect of the universe since the archetypes are

ineffectual by themselves.

Kepler sticks to this line even though, as he says, in this chapter the application of the

principle did not have a happy result. As Leibniz would say, our perceptions are confused and

indistinct so the final arbiter on all of our a priori reasoning, however cogent it may be, is the

physical universe, i.e. the works of God’s finger.

Alternative views of the Creator’s mind

Given that the conception of the Creator’s mind was so important to Leibniz and Kepler

among other scientists in formulating their a priori conceptions, it is apt to mention some

contemporary views of the Creator’s mind.

Bruce Lipton comes close to saying that a study of the universe is a study of a mind; we add

that the only mind that that could be is that of the Creator.669 He writes that, “Physicists are

being forced to admit that the universe is a ‘mental’ construction.” Leibniz is clear that the

universe is not a mental construction in the sense of being an illusion, and that the universe

exists independently of any single mind including the mind of God.

Richard Conn Henry writes that the universe has a mental nature. However, he seems to be

verging on Kantian subjectivism. Elsewhere, he quotes Sir James Jeans, “The stream of

knowledge is heading toward a nonmechanical reality; the universe begins to look more like a

666 Huggard, E.M. (trans.), Leibniz, G. W. Theodicy: Essays on the Goodness of God, the Freedom of Man and

the Origin of Evil Released 24 Nov 2005 [EBook #17147] from C.J. Gerhardt's Edition of the Collected

Philosophical Works, 1875-90 La Salle, Illinois 61301 667 Leibniz, G.W. Tentamen anagogicum c.1696, in Loemker, pp.477-9 668 Duncan, A.M. (trans.), Kepler, J., Mysterium Cosmographicum Abaris Books, Janus Series, Opal Publishing

1981 p.125, footnote 2, fifth-last line 669 Lipton, B. “Embracing The Immaterial Universe Toward a New Noetic Science” Shift: At the Frontiers of

Consciousness No. 9, Dec 2005-Feb 2006, pp. 8-12 the quarterly publication of the Institute of Noetic

Sciences (IONS); website: www.noetic.org accessed at http://www.brucelipton.com/biology-of-

belief/embracing-the-immaterial-universe

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great thought than like a great machine. Mind no longer appears to be an accidental intruder

into the realm of matter … we ought rather hail it as the creator and governor of the realm of

matter.” However such snippets and references to quantum physics as Henry indulges in

remind of the quasi-scientific essays of the now-discredited postmodern milieu.670

While Henry has only quoted Jeans in brief, and so we cannot be sure of Jeans’ full meaning,

we would not agree that the universe is merely a thought. Leibniz made it clear that the

universe is real and is separate from God. It is true that God can create with merely an act of

will which is arguably tantamount to a mental act, but in doing so God creates something that

is separate and independent of his mind.

Superficially Henry appears to agree with our contentions regarding Leibniz’s conception of a

priorism and the power of a priorism, because by understanding God’s mind before or

without observation we can understand physics. Nonetheless, for the reasons explained, we

distance ourselves from Henry’s position.

Conclusion

We have shown that a priori thought played at least a key enabling role in three examples,

namely, in the development of the calculus, non-Euclidean geometry and the Keplerian theory

of the solar system. By becoming more aware of the a priori foundations of other scientific

domains and of science today in general, the study of a priori foundations may receive a fillip

which will allow for greater benefit to be derived from experimental efforts. Equally

importantly, a new array of theories may arise from contradictory or unexplained

experimental data already collected.

670 Henry, R.C. “The Mental Universe” Nature 436: 29, 2005

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Chapter 10: Conclusion – Leibniz’s humanist and Neoplatonic agenda

Introduction

In this short final chapter, we recap on Leibniz’s historical role and describe Leibniz’s agenda

referred to in the thesis title. Leibniz continued an ancient “agenda” certainly of the

Neoplatonists but also pre-dating the Neoplatonists to the Egypt of Hermes Trismegistus and

perhaps before that. In Chapter 3, it was explained how Leibniz helped usher in modernity.

Chapter 4 through 9 explored how Leibniz helped define, direct and fight for the kind of

thinking – and the kind of thinking about thinking – that the onset modernity relied upon. For

modernity to shift upwards rather than collapse, it would be well to maintain Leibniz’s

methods and orientation, and undertake some of Leibniz’s projects which have been embraced

in a serious way by only a few, such as the Universal Characteristic.

Leibniz and humanism

To compare Leibniz’s view of Man with that of other thinkers, such as Kant, is beyond the

scope of this thesis. However, an account of Leibniz’s metaphysics and the underpinnings of

his approach to science requires mention of his conception of Man’s nature and Man’s role in

the universe. In this, Leibniz was in the humanist tradition of Dante and distinguished from

the quasi-mystical, albeit at the same time somewhat Christian humanist, attitude of Leibniz’s

British contemporaries such as Boyle. Leibniz might not have said like Dante that humanity is

the jewel of Creation or the highest part of Creation, but he did say that humanity and humans

can act like the Divine in the miniature. This is not far from saying that humanity has a special

place in Creation, for Leibniz did not say that any other kind of creature can act like the

divine in miniature.

It must be asked what it means that Man is able to reason in the way that he can. Kepler put

this down to the uniqueness of Man in all Creation and the special role that God prescribed

for Man by giving Man the power of Reason. If nothing else, it can be concluded that there is

something special about Man. From here, it is easy to enter the Dantean Humanist

Renaissance. Leibniz was the kind of humanist that Pico della Mirandola and Giordano Bruno

were, who regarded Man as magus who can arrogate and wield great power and effect vast

change in the universe like a race of gods. As mentioned in this thesis, this is aligned with the

Hermetic conception of humankind.

Human progress

The intention to benefit humankind is implicit in Leibniz’s descriptions of, and optimistic

hopes for, human knowledge and in his idea of progress. For Leibniz, progress in itself and

progress for humankind were synonymous. Leibniz wrote and promoted designs for social

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organisation to promote improvements in culture and knowledge among the general

population, believing that the best of human attainments were intellectually and morally

accessible to all people.

Leibniz was at a historical juncture which he helped create. He was a classicist and a

medievalist himself. He was a conciliatory eclectic thanks to Thomasius as Leibniz’s teacher

and also thanks to the efforts of Thomasius to ensure a lasting peace after the Thirty Years

War.

Leibniz’s optimism is inherent in his best of all possible worlds doctrine. This doctrine is the

logically necessary and otherwise natural outcome of Leibniz’s metaphysics and its interplay

with his theology. In many ways, Leibniz’s metaphysics is contained in or is at least derivable

from his theology.

Broadening the field of debate for Platonism

Leibniz was a universalist and “Renaissance man” who helped create modernity with all of

the power of modern rigor. No longer was it Cusa arguing against the Aristotelians on

metaphysical grounds. Rather, it was a Renaissance-type humanist arguing against the neo-

Aristotelians, Averroists and Empiricists on many grounds other than metaphysical. Leibniz

combined the power of the Platonic dialogue with the scientific success of Kepler and

Galileo, and with his own and his associates’ achievements in mathematics, invention,

machinery, metaphysics and physics.

Considering the big questions first

In Chapter 9, it was shown that working through the steps of discovery for fundamental

questions of theology and metaphysics can affect where we end up in the natural sciences.

Conversely, as Riemann indicated and as Leibniz allowed, empirical discoveries can indicate

where our a priori reasoning went wrong. To address the basic questions in metaphysics while

conducting work in the natural sciences was always the approach of the Neoplatonists. That

background work forms the largest context for natural science. Our answers to the “big” a

priori questions can be tested with our work in the natural sciences. That background work,

the “big” a priori questions, must include the nature of humankind and the role of humankind.

This is because in a universe resulting from the Creator, minds with the capability to address

such questions first of all cannot be accidental and have a purpose different from that of, say,

the nearest passing meteor.671

Human capability

The nature of the universe cannot be understood without including the role of humans as

physical force and as a uniquely dynamic law of nature. Humanity’s capability and potential

671 Also see Penrose, R. The Emperor’s New Mind Penguin 1991

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to exercise its power as collective magus or as a wilful physical force must be taken into

account. Related endeavours such as investigations in mathematics are aided or hindered by

the scaffolding provided by the culture as much as anything else, which includes the

language, art, literature, music as well as philosophy, mathematics (of whatever kind) and

science of the age, which creates conditions for particular kinds of thought to flourish. How

does a culture develop conditions conducive to particular kinds of thought and creativity? We

can say that a culture’s preoccupation with a particular class or kind of Platonic ideas, absent

interruptions caused by war, deliberate sabotage or other factors, may lead to a raft of

discoveries in that domain over successive generations. Such discoveries can feed into

economic, military and cultural breakthroughs creating prosperity for the civilisation or

culture concerned. The political framework and conception of humanity that creates social

fertile conditions for any such flourishing of thought was of great interest to Leibniz. He

promoted related ideas through his circle of influence.

Human knowledge

Leibniz to our knowledge did not use Cusa’s term docta ignorantia “learned ignorance”. He

was optimistic about what was already known and not written down or organised. He was

more optimistic still, and even excited, about what humans would come to know in the future.

He sometimes seemed a little daunted by the extent of what humanity does not know. Even

though Leibniz was aware of the rigor and power of mathematical tools, he did not believe

that everything could be explained or subsumed by mathematical methods.

In responding to Descartes’ Principia Philosophie Part I point-by-point in 1692, Leibniz

wrote about the horizons of human knowledge:672

On Article 26. Even though we are finite, we can yet know many things about the

infinite: for example, about asymptotic lines, or lines which approach each other

continuously when infinitely produced but never meet; about spaces which are infinite

in length but not greater in area than a given finite space; and about the sums of

infinite series. Otherwise we should also know nothing with certainty about God.

However, it is one thing to know something about a matter and another to comprehend

the matter, that is, to have within our power all that is hidden in the matter.

On what humans can know and what humans should investigate:

On Article 28. As for the end God has proposed to himself, I am fully convinced both

that they can be known and that it is of the highest value to investigate them; and that

to disdain this inquiry is not without danger or suspicion. In general, whenever we see

anything that is particularly useful, we may safely assert that one, among others, of the

ends which God has proposed to himself in creating this thing is precisely to render

these services, since he both knew and planned this use of it. I have elsewhere pointed

out, and shown by examples, that certain concealed physical truths of great importance

672 Loemker, L. E., trans. and ed., Gottfriend Wilhelm Leibniz: Philosophical Papers and Letters 2nd ed. D.

Reidel Publishing Company, Dordrecht Hollard 1969, p.387; first ed. 1956 University of Chicago Press,

Chicago

Page 195

can be discovered by considering final causes, which not have been discovered as

easily by efficient causes.

Considering final causes is tantamount to pursuing an a priori program. Article 28 also states

that no phenomenon in the universe is accidental, and the deliberate causes of things are

knowable by humans.

A new metaphysics as a blueprint for the good in human society

We referred to Loemker in Chapter 3 who said that Leibniz had hoped his metaphysics

“would be adopted and made a blueprint, so to speak, by men of good will (honestas) for the

restoration of European order”.673 Counterposed to Leibniz was an “alternative interpretation

of human nature, human thought, and the good”. Loemker places this under the subheading

“The New Way of Ideas: Locke” and that new way is based on “another theory of ideas – that

of nominalism and positivism”.674

Mercer’s thesis on Leibniz makes much of the concept of “conciliatory eclecticism”.675 To be

sure, much of Leibniz’s work and thought can be regarded in this way. Raynaud begins his

commentary by saying, “In comparison to Descartes, or Hobbes, or Locke, Leibniz presents

himself as a moderate or a conciliator: he means to rescue a portion of the heritage of Plato

and Aristotle, he rejects Hobbes’s radical nominalism as well as his legal positivism, and he

breaks with Cartesian mechanism in order to make a significant place for natural

teleology.”676

Flexibility in scientific method, and the ultimate journey

In Chapter 6 under the heading “Science may use indemonstrables”, Raynaud’s conclusions

were given regarding Leibniz’s pragmatism. For Leibniz, methodological doubt was not a

reason to forego deny useful benefits derived from particular lines of enquiry.677 Further, the

requirement to answer a priori questions before conducting was also not absolute though it

can lend great power. “For,” Raynaud says, “if science may employ indemonstrables, that also

means that the initial absence of such principles does not impede one from progressing on the

path of reason, without having to ‘cast into doubt’ common beliefs.”678 For Leibniz, there are

many useful and legitimate paths. For Raynaud, Leibniz “establishes a new continuity

673 Loemker, L. E. Struggle for Synthesis: The Seventeenth Century Background of Leibniz’s Synthesis of Order

and Freedom Harvard University Press: Cambridge USA 1972, p.127 674 Ibid., pp.127-8 675 Mercer, C. Leibniz’s Metaphysics: Its Origins and Development Cambridge University Press: Cambridge,

2001, pp. 80-110 676 Raynaud, P. “Leibniz, Reason and Evil” in McCarthy, J. C., ed. and trans. Modern Enlightenment and the

Rule of Reason CUA Press Washington D.C. 1998, p.150 677 Ibid., p.152 678 Ibid.

Page 196

between science and the active life, between knowledge and practical judgement, and between

reason and faith.” 679

Benefit to humankind is but a self-evidently good side-effect of the seeking after the kingdom

of God. We will end with Leibniz’s words in which he reiterates Kepler’s advocacy of seeking

scientific insight to improve ourselves but, unlike Kepler, he also recognises the pragmatic

benefits to the day-to-day lives of humans made possible by scientific endeavour:680,681

I have shown on several occasions that the final analysis of the laws of nature leads us

to the most sublime principles of order and perfection, which indicate that the universe

is the effect of a universal intelligent power.682 As the ancients already held, this truth

is the chief fruit of our investigations; without mentioning Pythagoras and Plato,

whose primary aim was such an analysis, even Aristotle sought to demonstrate a prime

mover in his works, particularly in his Metaphysics. It is true that these ancient

thinkers were not informed about the laws of nature as are we since they lacked many

of the methods which we have and of which we ought to take advantage. The

knowledge of nature gives birth to the arts, it gives us many means of conserving life,

and it even provides us with conveniences; but the satisfaction of spirit which comes

from wisdom and virtue, in addition to being the greatest ornament of life, raises us to

what is eternal, whereas this life, in contrast, is most brief. As a result, whatever serves

to establish maxims which locate happiness in virtue and show that everything follows

the principle of perfection is infinitely more useful to man, and even to the state, than

all that serves the arts. Discoveries useful to life, moreover, are very often merely the

corollaries of more important insights; it is true here too that those who seek the

kingdom of God find the rest on their way.

679 Ibid. 680 Plauché, G. A. writes in his essay Ancient vs. Modern Political Thought 9 April 2011, “The premodern

political philosophers whose thought achieved dominance – Plato, Aristotle, Cicero, Augustine, Aquinas, and

others – were primarily concerned with the search for right order. They generally accepted essentialism,

teleology, eudaimonism, and natural law-type virtue or deontic ethics. Modern political philosophers tend to

be more concerned with the search for peace and order, consequentialist or deontic ethical systems concerned

primarily with social order, and are more likely to be rationalists or empiricists and base their theories on

reductionist foundations.” In this sense, Kepler’s philosophy was more pre-modern while Leibniz’s was

modern. Accessed at http://gaplauche.com/blog/2011/04/09/ancient-vs-modern-political-thought/ 12 May

2011 681 Leibniz, G. W. c1696 “Tentamen Anagogicum: An anagogical essay in the investigation of causes” Loemker

1969, p.477 682 These are precisely the words of Cicero in De natura rerum. Also see Boyle V, 515ff. quoted in Burtt, E.A.

The Metaphysical Foundations of Modern Physical Science Routledge London 1932 2nd ed. reprinted 1950

p.189, “the consideration of the vastness, beauty, and regular motion of the heavenly bodies; the excellent

structure of animals and plants; besides a multitude of other phenomena of nature, and the subserving of most

of these to man; may justly induce him as a rational creature, to conclude, that this vast, beautiful, orderly,

and (in a word) many ways admirable system of things, that we call the world, was framed by an Author

supremely powerful, wise and good, can scarce be denied by an intelligent and unprejudiced considerer.”

Page 197

Leibniz’s policy for nations

With Leibniz, the humanist conception of Man as magus and as the jewel of Creation was

crystallised in pragmatic policy and, in particular, in national government policy. Leibniz was

born in 1647 the year before the Treaty of Westphalia. This treaty enshrined the doctrine of

national sovereignty in the law of nations, and established the modern nation state system,

which today is known as the Westphalian system.

Leibniz was partly a product of the optimism inevitably brought by the end of the Thirty Years

War (1618-1648) as well as of the cultural optimism of his milieu. For example, Bach lived

and worked in Leipzig at the same time as Leibniz though it is not known whether they knew

each other. The possibilities of the new era were being conceived during Leibniz’s lifetime

and Leibniz helped conceive them. Leibniz and Denis Papin were early recruits into the

Academy of Sciences in Paris under its inaugural leader Christian Huygens. The Academy

was charged by Louis XIV with developing new power sources for France. Thus, it was a

scientific academy with a national and industrial purpose. From the start, Leibniz was forced

to grapple with the idea of power and of increasing Man’s physical power. He accepted the

challenge. Leibniz came to understand partly by exposure to Huygen’s gunpowder

experiments that controlled explosive force had a higher order of potential than the passive

force emphasized by the ancients. Perhaps inspired by the mission of the French academy,

Leibniz later advised Tsar Peter the Great to establish the Russian Academy of Sciences. Tsar

Peter agreed and invited Leibniz to be its first president, though Leibniz declined that offer

partly due to his existing responsibilities and commitments, and – possibly – partly because

Russia was regarded as a dangerous place. In any case, Leibniz’s circle of influence included

many nations other than France and Russia.

In the Westphalian era, the idea of Man as magus was coming into its own, and was being

enshrined in forward-thinking policy by European and Eurasian leaders partly under Leibniz’s

influence. The concept of Man as magus emerged from Neoplatonism. It was joined at the hip

with the optimistic conception of a plentiful and vast physical universe, in which Man has a

decisive and central role. Arguably, it was for promoting such plenitude and optimism against

the established fixedness of prevailing policy that Giordano Bruno was burned at the stake.

Far from being mystical, vague or otherwise divorced from reality, the Neoplatonic

orientation was a living force which demanded that humanity adopt the scientific stance and

take its rightful place as commander of itself and of the universe. Leibniz’s legacy survives

today in the policies of scientific-industrial nation state. A month before the closing words of

this thesis were written, the NASA rover Curiosity landed on Mars. Leibniz would be pleased,

but much remains to be done.

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Appendix 1: To the greater glory of God

The entirety of what follows in this Appendix is a quote from an anonymous circular which

we have reason to believe was written by Leibniz. It is referred to in Chapter 3 of this thesis.

Ad majorem Dei gloriam [“to the greater glory of God”]683

Profound meditation is urged upon researchers concerning the propulsive power of

gunpowder; and their perceptive intelligence is challenged to realize the possibility of

diverting the vast power of gunpowder to healthier applications than those hitherto

known. Only irreverent thinking can deny such an incontrovertible truth as that in the

sight of God only wholesome applications and uses appertain to all that is created and

can be manufactured therefrom; for everything exists for the benefit of mankind, if

only they had a serious desire for it. Nevertheless it is only too well known that the

corrupted and misled spirit of man is concerned in countless cases not with salutary

application, but allows itself to become passionately concerned with applying all its

acumen to discovering how to misuse things, which according to the intention of the

Creator should be useful to mankind, so that they should have every cause to praise

him on their account.

Such misuse had induced some men to describe the discoverer of gunpowder simply

as a sorcerer in monk’s garb instructed by satan; for owing to its violent power it

seems impossible to achieve aught but explosions, loss of life and destruction.

Similarly doubtless in the immemorial past, people thought of the propulsive power of

flowing water and of wind, before they had been made serviceable for useful purposes

for mankind by wise and industrious mechanical craftsmen who used first simple

wheels and later toothed wheels. The above mentioned view of the satanic origin of

gunpowder should therefore be set aside and replaced by the following:

1. The inventor of gunpowder, whoever he was, was a capable chemist.

2. The skilful achievements of chemistry are hated neither by God nor by Nature, nor

are they directed against God’s will; since they can instantly convert active poisons

into blessed and healing potions.

3. It is possible by means of some form of control to force the aforesaid propulsive

power of gunpowder, however sudden and violent it may now be, into ordered

channels, so that it should be adaptable depending on the arrangements made for

driving an ordinary mill or for performing other work; and this aim may be obtained if

earnest prayer for divine support is combined with enthusiastic pyro-mechanical

labours, and if mind and hand are ceaselessly busied with this work; and above all if

the aforementioned fundamental demonstration [of a pious use of the gunpowder and

the praise of the Almighty Creator are kept in mind, - rather than its direct tangible

683 Klemm from Ad majorem Dei gloriam published in Nouvelles de la Republique des Lettres Amsterdam 1695,

pp. 218-220

Page 199

use, which divine Providence will in its wisdom confer on the present century or on

future ones.

More than two and a half years have elapsed since a number of researchers were

publicly charged with the said problem concerning gunpowder, namely that it could

and should be used for other purposes than hitherto. And the researchers should

thereby be urged to the bold attempt gradually to give up their enthusiastic researches

which were placing the misapplied use of the violent power of gunpowder . . . in a

very favourable light. And at the same time they were to devote a part of their efforts,

for the glory of the Creator, to discovering a new use for gunpowder, which had been

latent in it from the beginning but had gone unheeded, because all who have hitherto

occupied themselves with its application have stood under the spell of that terrible

misconception that gunpowder was useful only for an idle and wasteful display of its

flashes and flying sparks, or else to wound, to kill, to explode, to burst, to ruin, in short

to unhinge the whole world. It is but too easy to suppose that our researchers, under

the influence of this prejudice, have given either no thought or not sufficiently serious

thought to a useful application of gunpowder, especially as no prospect of an

important or obvious application attracted them in this direction. Only one man has

been found who, with a view to a possible advantageous application, has freed himself

from the above mentioned preconceived opinion … and has honoured the attempt with

his attention, in a French letter of the 24 May 1686.

‘I have received the problem communicated by you concerning a new

application of gunpowder. In my opinion it may certainly be hoped to attain

this end. Seven or eight years ago I showed to Monsieur Colbert an engine

which I had had built for this very purpose, and which was illustrated in the

Proceedings of our Academy.

‘It worked as follows; a tiny quantity of gunpowder, about a thimbleful, was

able to raise some 1,600 lb. five feet high; and not with such violence as is

usual, but with moderate and steady power. Four or five servants, whom

Monsieur Colbert ordered to pull the rope attached to the engine, were quite

easily lifted up into the air. Nevertheless there was a certain difficulty in

constantly reproducing this Power.’

The writer of this letter communicated two quite unusual and really incomparable

discoveries:

1. One or two drachmas of gunpowder, a thimbleful, will raise a weight of 1,600 lb.

five feet; and furthermore,

2. This occurs without the usual violence, but with moderate and steady power.

The first of these discoveries arouses admiration, but is in conformity with principles

already accepted. The effectiveness of the powder could naturally be increased either

by addition of more powder or by improvement of the piston. Nevertheless the second

discovery would appear to extend beyond these known principles, and must be the

Page 200

more highly valued since it approaches the miraculous. Doubtless therefore all those

who are plagued by curiosity to see this simple and really useful experiment could take

the trouble to make such a machine or another which is suitable to impel any weight

chosen as desired. They should allow themselves to be helped therein by men who are

familiar not only with the use and misuse of gunpowder but also with the art of

mechanics. Especially they will need for this, the magnificent work of the late

Monsieur Bondel The Art of Shooting with iron balls filled with powder, a work that

would perhaps be more correctly entitled “The Art of Thoroughly Understanding the

Nature and Characteristics of Natural and Violent Motion”. In it will be found many

demonstrations directed toward the aim here mentioned. And there can no longer be

any doubt that the fact that a tiny quantity of powder can raise 1,600 lb. so high, can,

some day, be put to general use as soon as an inventor turns his attention to solving the

many difficulties, especially those which obstruct the repetition of regular action. It

remains only to add that at this point besides the description and exhibition, a drawing

of the machine itself could very easily have been shown, by means of which its

manner of working could have been shown; did not the ease with which this can be

manifested and understood seem to make this quite superfluous, especially since its

effectiveness has already been more than sufficiently demonstrated. Moreover, gifted

investigators have had sufficient reason to believe positively that the making of such

experiments, all too rare, each of which needs special consideration, may ultimately

lead to a fruitful contribution useful to everyone.

Meantime, the decision rests with God alone. He will according to his merciful

judgment at the right time make it evident that all creation is appointed for the welfare

and service of mankind. It is therefore the duty of man not only to believe this truth,

but to work with all his power that he may use and enjoy everything with

acknowledgement and gratitude. Praised therefore be the most holy name of Him

through whose goodness the first stage of this apparent impossibility (namely the

useful application of gunpowder) has been overcome; Praised, say I, be his name to all

eternity! Amen.

Page 201

Page 202

Appendix 2: A proof from basics

The entirety of what follows in this Appendix is a quote from a letter by Leibniz.

Tentamen anagogicum [“an essay proceeding from the basics to prove something firm”]684

The inquiry into final causes in physics is precisely the application of the method

which I think ought to be used, and those who have sought to banish it from their

philosophy have not adequately considered its usefulness. For I do not wish to do them

the injury of thinking that they have evil designs in doing this. Others followed them,

however, who have abused their position, and who, not content with excluding final

causes from physics but restoring them elsewhere, have tried to destroy them entirely

and to show that the Creator of the universe is most powerful, indeed, but without any

intelligence. There have been still others who have not admitted any universal cause,

like the ancients who recognized nothing in the universe but a concourse of

corpuscles. This seems plausible to those minds in whom the imaginative faculty

predominates, because they believe that they need to use only mathematical principles,

without having any need either for metaphysical principles, which they treat as

illusory, or for principles of the good, which they reduce to human morals; as if

perfection and the good were only a particular result of our thinking and not to be

found in universal nature.

I recognize that it is rather easy to fall into this error, especially when one’s thinking

stops at what imagination alone can supply, namely, at magnitudes and figures and

their modifications. But when one pushes forward his inquiry after reasons, it is found

that the laws of motion cannot be explained through purely geometric principles or by

imagination alone. This is also why some very able philosophers of our day have held

that the laws of motion are purely arbitrary. They are right in this if they take arbitrary

to mean coming from choice and not from geometric necessity, but it is wrong to

extend this concept to mean that laws are entirely indifferent, since it can be shown

that they originate in the wisdom of their Author or in the principle of greatest

perfection, which has led to their choice.

This consideration gives us the true middle term that is needed for satisfying truth as

well as piety. We know that while there have been, on the one hand, able philosophers

who recognized nothing except what is material in the universe, there are, on the other

hand, learned and zealous theologians who, shocked at the corpuscular philosophy of

and not content with checking its misuse, have felt obliged to maintain that there are

phenomena in nature which cannot be explained by mechanical principles; as for

example, light, weight, and elastic force. But since they do not reason with exactness

in this matter, and it is easy for the corpuscular philosophers to reply to them, they

injure religion in trying to render it a service, for they merely confirm those in their

error who recognize only material principles. The true middle term for satisfying both

684 c.1696, Loemker 1969, pp.477-9

Page 203

truth and piety is this: all natural phenomena could be explained mechanically if we

understood them well enough, but the principles of mechanics themselves cannot be

explained geometrically, since they depend on more sublime principles which show

the wisdom of the Author in the order and perfection of his work.

The most beautiful thing about this view seems to me to be that the principle of

perfection is not limited to the general but descends also to the particulars of things

and of phenomena and that in this respect it closely resembles the method of optimal

forms, that is to say, of forms which provide a maximum or minimum, as the case may

be - a method which I have introduced into geometry in addition to the ancient method

of maximal and minimal quantities. For in these forms or figures the optimum is found

not only in the whole but also in each part, and it would not even suffice in the whole

without this. For example, if in the case of the curve of shortest descent between two

given points, we choose any two points on this curve at will, the part of the line

intercepted between them is also necessarily the line of shortest descent with regard to

them. It is in this way that the smallest parts of the universe are ruled in accordance

with the order of greatest perfection; otherwise the whole would not be so ruled. It is

for this reason that I usually say that there are, so to speak, two kingdoms even in

corporeal nature, which interpenetrate without confusing or interfering with each other

- the realm of power, according to which everything can be explained mechanically by

efficient causes when we have sufficiently penetrated into its interior, and the realm of

wisdom, according to which everything can be explained architectonically, so to

speak, or by final causes when we understand its ways sufficiently. In this sense one

can say with Lucretius not only that animals see because they have eyes but also that

eyes have been given them in order to see, though I know that some people, in order

the better to pass as free thinkers, admit only the former. Those who enter into the

details of natural machines, however, must have need of a strong bias to resist the

attractions of their beauty. Even Galen, after learning something about the function of

the parts of animals, was so stirred with admiration that he held that to explain them

was essentially to sing hymns to the honor of divinity. I have often wished that an able

physicist would undertake to prepare a special work whose title - or whose aim at least

- would be The Hymn of Galen.

Page 204

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