teach me to think: developing thinking skills, it’s what sets us apart
TRANSCRIPT
Teach Me to Think:Developing Thinking Skills,
It’s what sets us apart.
What is Critical Thinking?
• Focused thinking
• Thinking with a definite purpose (goal)– Can be a complex & involved process
• An active process that involves constant questioning
Why we need Critical Thinking students
• “The significant problems we face cannot be solved at the same level of thinking we were at when we created them.”
• An Albert Einstein Quote on Creativity
What are the Goals of Critical Thinking?
• Finding Meaning• Seeking Logic• Searching for reason• Looking answers• Developing facts and opinions• Appreciating different points of view
How Can I develop my Critical Thinking Skills?
• Think about your thinking• Think about why you make your choices
and decisions• Think about why the world is the way it is• Practice every day!
– Word problems– Math problems– Puzzles– Games of strategy
Critical Thinking and Reasoning
Chapter 2 introduces
INDUCTIVE and DEDUCTIVE Reasoning
These types of Reasoning are essential to CRITICAL THINKING
Lesson 2.1 Inductive Reasoning in Geometry
Objectives:
1) Use inductive reasoning to find the next term in a number or picture pattern
2) To use inductive reasoning to make conjectures.
HOMEWORK: 2.1/1-15 odds
Inductive reasoning: • make conclusions based on patterns you
observe
Conjecture: • conclusion reached by inductive reasoning
based on evidence
Geometric Pattern:• arrangement of geometric figures that repeat
Inductive Reasoning – Is reasoning that is based on patterns you observe.
If you observe data, then recognize a pattern (the rule) in a sequence you can use inductive reasoning to find the next term.
Ex. 1: Find the next term in the sequence:A) 3, 6, 12, 24, ___, ___
B) 1, 2, 4, 7, 11, 16, 22, ___, ___
C)
48 96 Rule: x2
29 37 Rule: +1, +2, +3, +4, …
Rule: divide each section by half
Inductive Reasoning
1. Process of observing data
2. Recognizing patterns
3. Making generalizations based on those patterns
An example of inductive reasoning
Suppose your history teacher likes to give “surprise” quizzes.
You notice that, for the first four chapters of the book, she gave a quiz the day after she covered the third lesson.
Based on the pattern in your observations, you might generalize that you will have a quiz after the third lesson of every chapter.
Find the next item in the pattern.
Identifying a Pattern
January, March, May, ...
The next month is July.
Alternating months of the year make up the pattern.(skip every other month)
Observe the data..
state the pattern.
identify the pattern..
Find the next item in the pattern.
Identifying a Pattern
7, 14, 21, 28, …
The next multiple is 35.
Multiples of 7 make up the pattern.(add 7 to each term to get the next)
Observe the data..
state the pattern.
identify the pattern..
Find the next item in the pattern.
Identifying a Pattern
In this pattern, the figure rotates 90° counter-clockwise each time.
The next figure is .
Inductive reasoning can be used to make a conjecture about a number
sequence
Consider the sequence 10, 7, 9, 6, 8, 5, 7, . . .
Make a conjecture about the rule for generating the sequence.
Then find the next three terms.
Solution
10, 7, 9, 6, 8, 5, 7, . .
Look at how the numbers change from term to term
The 1st term in the sequence is 10.
You subtract 3 to get the 2nd term.
Then you add 2 to get the 3rd term.
You continue alternating between subtracting 3 and adding 2 to generate the remaining terms.
The next three terms are 4, 6, and 3.
Find the next item in the pattern
0.4, 0.04, 0.004, …
Rules & descriptions can be stated in many different ways:
Multiply each term by 0.1 to get the next.
Divide each term by 10 to get the next.
When reading the pattern from left to right, the next item in the pattern has one more zero after the decimal point.
The next item would have 3 zeros after the decimal point, or 0.0004.
Identifying a Pattern
Arrangement of geometric figures that repeatUse inductive reasoning and make conjecture as to the next
figure in a pattern
Use inductive reasoning to find the next two figures in the pattern.
Geometric Patterns
Use inductive reasoning to find the next two figures in the pattern.
Geometric Patterns
Describe the figure that goes in the missing boxes.
Describe the next three figures in the pattern below.
Geometric Patterns
Lesson 2.1 – Inductive Reasoning
Objectives:
1) Use inductive reasoning to find the next term in a number or picture pattern
2) To use inductive reasoning to make conjectures.
Homework: WS 2.1
Mathematicians use Inductive Reasoning to find patterns which will then allow
them to conjecture.
We will be doing this ALOT this year!!
Conjectures
A generalization made with inductive reasoning (Drawing conclusions)
EXAMPLES:• Bell rings M, T, W, TH at 7:40 am
Conjecture about Friday?
The bell will ring at 7:40 am on Friday
• Chemist puts NaCl on flame stick and puts into flame and sees an orange-yellow flame. Repeats for 5 other substances that also contain NaCl also producing the same color flame.
Conjecture?
All substances containing NaCl will produce an orange-yellow flame
Finding Patterns• 2, 4, 7, 11, ...
– Rule? Add the next consecutive integer– Next 3 terms?
• 16, 22, 29
• 1, 1, 2, 3, 5, 8, 13, ...– Rule? Add previous two terms
(Fibonacci Sequence)– Next 3 terms?
• 21, 34, 55
• 1, 4, 9, 16, 25, 36, ...– Rule? Add consecutive odd numbers OR
the perfect squares– Next 3 terms?
• 49, 64, 81
Make a conjecture about the sum of the
first 30 odd numbers.
1 = 1
1 + 3 = 4
1 + 3 + 5 = 9
1 + 3 + 5 + 7 = 16
1 + 3 + 5 + 7 + 9 = 25
..
1 + 3 + 5 +...+ 61 =
= 12
= 22
= 32
= 42
= 52
..
= 302900
cont.: Make a conjecture about the sum of the first 30 odd numbers.
Conjecture:Sum of the first 30 odd numbers =
= the amount of numbers added
Sum of the first odd numbers =
To show that a conjecture is always true, you must prove it.
To show that a conjecture is false, you have to find only one example in which the conjecture is not true. This case is called a counterexample.
A counterexample can be a drawing, a statement, or a number.
Truth in Conjectures
Inductive Reasoning assumes that an observed pattern will continue.
This may or may not be true.Ex: x = x • x
This is true only for x = 0 and x = 1
Conjecture – A conclusion you reach using inductive reasoning.
Counter Example – To a conjecture is an example for which the conjecture is incorrect.
The first 3 odd prime numbers are 3, 5, 7. Make a conjecture about the 4th.
3, 5, 7, ___One would think that the rule is add 2, but that gives us 9 for the fourth prime number.
Is that true?What is the next odd prime number?
11
No
Show that the conjecture is false by finding a counterexample.
Finding a Counterexample
For every integer n, n3 is positive.
Pick integers and substitute them into the expression to see if the conjecture holds.
Let n = 1. Since n3 = 1 and 1 > 0, the conjecture holds.
Let n = –3. Since n3 = –27 and –27 0, the conjecture is false.
n = –3 is a counterexample.
Show that the conjecture is false by finding a counterexample.
Two complementary angles are not congruent.
If the two congruent angles both measure 45°, the conjecture is false.
45° + 45° = 90°
Finding a Counterexample
Show that the conjecture is false by finding a counterexample.
The monthly high temperature in Abilene is never below 90°F for two months in a row.
Monthly High Temperatures (ºF) in Abilene, TexasJan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
88 89 97 99 107 109 110 107 106 103 92 89
The monthly high temperatures in January and February were 88°F and 89°F, so the conjecture is false.
Finding a Counterexample
Supplementary angles are adjacent.
Show that the conjecture is false by finding a counterexample.
The supplementary angles are not adjacent, so the conjecture is false.
23° 157°
Finding a Counterexample
The radius of every planet in the solar system is less than 50,000 km.
Show that the conjecture is false by finding a counterexample.
Planets’ Diameters (km)
Mercury Venus Earth Mars Jupiter Saturn Uranus Neptune
4880 12,100 12,800 6790 143,000 121,000 51,100 49,500
Since the radius is half the diameter, the radius of Jupiter is 71,500 km and the radius of Saturn is 60,500 km. The conjecture is false.
Finding a Counterexample