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DIS-ALP

Disaster Information System of Alpine Regions

Berger Elisabeth, Grisotto Silvio, Hübl Johannes, Kienholz Hans, Kollarits Stefan, Leber

Diethart, Loipersberger Anton, Marchi Lorenzo, Mazzorana Bruno, Moser Markus, Nössing

Tanja, Riedler Walter, Scheidl Christian, Schmid Franziska, Schnetzer Ingo, Siegel

Hubert, Volk Gerhard

Final Report

Februay 2007

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PRISMA

Finalisation

2007-02-13 Version 1.0

PRISMA, IAN

Methodology

2006-06-29 Version 0.6

PRISMA

Portal,…

2006-06-21 Version 0.56

Bozen/Nössing

Projects in schools “Dealing

with natural hazards”

2006-06-21 Version 0.55

historical documentations

final version

2006-06-06 Version 0.5

Geoexpert

New Tools

finalisation

2006-06-06 Version 0.4

CNR IRPI Padova

New Tools

GPS tests and use of LIDAR

data

2006-05-17 Version 0.32

PRISMA

General content – Kick Off

2006-04-20 Version 0.2

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Table of contents

Table of contents .......................................................................................................................... 3

Introduction.................................................................................................................................. 7

Executive Summary ....................................................................................................................... 8

Methodology.............................................................................................................................. 9

Documentation support .............................................................................................................. 9

Implementation ........................................................................................................................10

Methodology ................................................................................................................................11

Introduction..............................................................................................................................11

Documentation on a national and regional level ..........................................................................12

Data entry forms ...................................................................................................................13

Additional information............................................................................................................14

Basic principles of DIS-ALP ........................................................................................................17

Methodology .........................................................................................................................17

Definitions.............................................................................................................................18

Event.................................................................................................................................18

Process groups, processes ..................................................................................................19

Phenomena........................................................................................................................21

Characteristics....................................................................................................................22

Collection standards ..................................................................................................................23

3W-standard .........................................................................................................................24

Annotation: “what“? ...........................................................................................................25

Annotation: “when“?...........................................................................................................25

Annotation: “where”? .........................................................................................................25

5W-standard .........................................................................................................................26

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Annotation: “who”? ............................................................................................................26

Annotation: “how” and “why”? ............................................................................................26

5W+ standard .......................................................................................................................27

Integration of standards into checklists and data bases ...............................................................27

Flow of information and data .....................................................................................................30

Flow of information................................................................................................................30

Reporter ............................................................................................................................31

Decision-maker ..................................................................................................................31

Documentalist ....................................................................................................................32

Preparatory measures ............................................................................................................32

Order of priority of the investigation .......................................................................................32

Investigation phase A .........................................................................................................33

Investigation phase B .........................................................................................................34

Investigation phase C .........................................................................................................34

Flow of data ..........................................................................................................................35

Technical guideline for event documentation ..............................................................................35

Basic cartographic considerations ...........................................................................................35

DIS-ALP Knowledge Base ..........................................................................................................38

Knowledge formalisation ........................................................................................................38

DIS-ALP knowledge as ontology .............................................................................................39

DIS-ALP ontology example .....................................................................................................40

DIS-ALP ontology use ............................................................................................................41

Documentation support ................................................................................................................42

New tools for geo-hazard documentation in the field and by remote sensing ................................42

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

Basic Principles - Experiences .................................................................................................43

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Implementation – Field trials and Results from the evaluation of the

applicability of modern remote sensing techniques ..................................................................45

Recommendations .................................................................................................................55

Instruction................................................................................................................................57

Introduction ..........................................................................................................................57

Field Guide............................................................................................................................57

Projects in schools “Dealing with natural hazards” ...................................................................59

Introduction.......................................................................................................................59

Principles of working with elementary and high school students ............................................59

Excursion on half a day with elementary school classes ........................................................60

Teaching unit with selected high school classes....................................................................61

Outlook..............................................................................................................................61

Implementation............................................................................................................................62

Introduction..............................................................................................................................62

Compilation and documentation of historical natural hazard events .............................................63

Procedure for the compilation and documentation of historical natural

hazard events........................................................................................................................63

Definition of the objectives of the study...............................................................................64

Historical sources and archives............................................................................................65

Interpretation of historical sources and extraction of the relevant

information ........................................................................................................................67

Description of the results ....................................................................................................70

Opportunities and limitations for the documentation of historical natural

hazard events........................................................................................................................71

Experiences of historical natural hazard events documentation (Institute of

Mountain Risk Engineering – IAN, BOKU) ................................................................................73

Spatial Planning and Risk management requirements ..................................................................74

Requirements for spatial planning .......................................................................................74

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Requirements for risk management .....................................................................................75

Requirements for the experts ..............................................................................................75

DIS-ALP web portal ...................................................................................................................76

Data integration into DIS-ALP portal .......................................................................................80

Bulk Insert of individual data...............................................................................................80

Setup of a DIS-ALP conforming Web Feature Service (WFS). ................................................81

Event Functionality ................................................................................................................82

DIS-ALP Web Services...............................................................................................................83

References...................................................................................................................................84

Project Consortium.......................................................................................................................89

Participants..................................................................................................................................90

Detailed annexes..........................................................................................................................94

Methodology (WP5) ...............................................................................................................94

System development (WP6) ...................................................................................................94

New Tools (WP7)...................................................................................................................95

Instruction ............................................................................................................................95

Implementation .....................................................................................................................95

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Introduction

Throughout the alpine regions natural disasters are a common threat to

human activities and development. The kind of natural disasters

distinguishes the alpine regions from non-mountainous regions of

Europe. The management of natural risks in a mountainous environment

and the prevention of disasters requires a broad and accessible

information basis. A high priority in the information needs may be

attributed to data about former disasters, which must be available as the

baseline for interdisciplinary and interregional research and provides an

important decision factor for common actions to prevent disasters and

deal with natural risks. But the information needs - defined by the

practitioners of spatial planning, risk prevention, civil protection and

catastrophe management - are not yet being met in terms of structured

data. DIS-ALP harmonises information basis and makes information more

easily accessible and integrated for spatial decision-making processes.

This improved and homogenised information provides the basis for

danger zoning and activity zoning as well as for regional and sectoral

spatial development concepts. For this end DIS-ALP results are available

in core working areas:

o Methodology

increase disaster information accessibility by common

methodology and knowledge base and thus improvement of

reliability and comparability of distaster information;

o Documentation support

improvement of field-documentation process via new tools and

hands-on instruction materials for documentation;

o Implementation

collect data about recent and historical events as database

information and provision of all results in DIS-ALP web portal;

Keywords: DIS-ALP, Natural Hazards, Event Documentation,

Information Technologies, Thesaurus and knowledge base

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Executive Summary

The documentation of natural hazards within the alpine range is

characterized by a large quantity of information, which often lacks

comparability and/or comprehensibility. Different responsibilities and

“traditions” of data collection as well as unstandardised storage of event

information pose difficulties in communication between organizations

(see Figure 1). This situation is further complicated by language barriers

and heterogeneous viewpoints of different disciplines.

Figure 1: Cornerstones of event documentation - current situation

DIS-ALP supports the documentation process of natural hazards by

sharing and complementing knowledge of different disciplines within

three major domains:

o Methodology

o Documentation support

o Implementation

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Methodology

Based on DOMODIS (Hübl et. al. 2002), the Methodology work package

(WP5) dealt with the basic requirements for a standardised event

documentation. DIS-ALP analysed and evaluated existing information

sources on a transnational basis. Practical and technical guidebooks for

event documentation were

developed, taking into account spatial

planning and civil protection. To

implement these data in a

cartographic environment, clear

definitions of features (“phenomena”)

as well as a generalized legend were

generated.

All results of methodological

considerations were formalised as a

knowledge-standard of natural

hazards. This knowledge base was realised as a specified domain-

ontology structuring DIS-ALP knowledge. It covers a wide range of terms

and background information in the field of natural hazards of alpine

regions. The emphasis is in the domain of event documentation realised

by the integration of an event documentation task-ontology.

In order to improve mutual understanding and interoperability between

different organisations the DIS-ALP knowledge base uses the

foundational ontology of WonderWeb (DolceLight). The DIS-ALP ontology

has been defined as multilingual and trans-disciplinary in order to

improve the communication between experts of different disciplines and

regions, the public and practitioners.

Documentation support

Innovative use of some up-to-date technologies and procedures in post-

event documentation surveys was declared as the main objective of work

package New Tools (WP7). Emphasis within this work package was the

development of field documentation tools and its practical test,

integrating GPS, mobile GIS and wireless communication as well as

Methodology

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remote sensing technologies for more efficient information collection and

improved documentation quality.

With the aim of broad knowledge transfer, work package 8, Instruction

(WP8), was responsible for the spreading of knowledge about the

standardised event documentation methodology among potential users.

Development of instruction materials and tutorials has been the main

objective within this work package. Instruction courses were held as

seminars, both as theory and field work courses.

Implementation

The work domain implementation covered a wide range of issues and

was based on the methodology developed.

First applications within the range of historical event

documentation were realised within work package

Implementations (WP9) in Bavaria (Germany),

Salzburg (Austria) and South Tyrol (Italy). Two different

approaches have been implemented. First focus was on

multiple events in a specified region during a defined

time period. The second approach focussed on single

events within a specified period of time.

To benefit from given standardised information a broadly accessible

information platform was developed as DIS-ALP web portal within work

package System Development (WP6). This platform seamlessly

integrates disaster information from partners institutions with DIS-ALP

knowledge base and thus supports disaster planning, management, and

communication. It integrates spatial information objects and GIS-based

methods of visualisation, querying and input, so that easy access for

experts and the public is guaranteed.

During the project period the DIS-ALP information platform was also

used for public dissemination of information and results as well as a

discussion forum for project partners and related institutions or experts.

Platform and web portal will continue to provide up-to-date information

beyond the official end of DIS-ALP.

Implementation

Support Tools

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Methodology

Introduction

Based on the results of the international project DOMODIS, efforts to

document natural hazards have been intensified in the alpine countries.

Several different methods and approaches have been developed in recent

years. Depending on regional or national requirements or organizational

conditions the focuses of event documentation are set differently.

One aim of DIS-ALP was a methodical unification of the immediate

documentation procedure of natural hazards. In work package 5 of

DIS-ALP a common standard or the minimum demands on the event

documentation, which can be expanded optionally, were defined. After

that, in a further step, the collected facts can be analysed and

interpreted. This approach enables adequately trained people to conduct

a primary documentation.

This report presents the most important elements of event

documentation. Moreover, it defines the used terms, determines

standards for the inquiry, demonstrates the transfer of data to data base

patterns and explains the flow of information and data. In the appendix

there are checklists and definitions for the further use.

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Figure 2: Structure of DIS-ALP Method

Documentation on a national and regional level

In the alpine countries there are different regulations for the legal,

organisational and structural conditions for the event documentation.

Generally, the documentation of hazardous events can only be carried

out successfully when appropriate legal and administrative conditions are

clearly fulfilled. This means that those people who are entrusted with the

documentation on site must have a distinct work order basing on legal

regulations.

As the experience from Switzerland shows, the idea of using local

observers has proved its value. The advantage is that these people are

familiar with local conditions and can quickly attend the location of an

event. Therefore, mainly forest officials and surveyors of roads are

consulted for this responsibility. The documentation is conducted by

using standardised forms or check-lists. Afterwards these data are

checked whether they are plausible and are filed in an appropriate shape

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(as a hardcopy or digitally in a data base). On the basis of this

verification more detailed or supplementary investigations can be

arranged. The available data are normally managed by the responsible

authority, whereas the responsibility depends on regional or national

conditions.

Top-quality documentation requires standardised forms and checklists.

Only this way, events can be compared and reconstructed for a later

analysis.

Event documentation in Switzerland, South Tyrol, Bavaria and Austria is

based on date entry forms, which, nevertheless, are different.

Data entry forms

The structures of the data entry forms of the above-named countries are

all about the same. Starting with the entry of basic data, concerning the

particular area (basic information), more detailed information, separated

by the kind of process, is registered afterwards.

The following processes can be distinguished:

o flood

o debris-flow

o avalanche

o slide

o stone fall (rock fall)

As an indicator for the quality of the data the so-called MAXO-Code has

gained acceptance. This MAXO-Code has already been regarded as

decisive in the DOMODIS project.

The data can be attributed to the following criteria:

M measured data, observation

A estimation of data

X not clear, to investigate

O unknown, investigation impossible

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Additional information

In Bavaria an event is localised in a GIS data base (HANG) by means of

x/y-coordinates. References to photographs, videos and publications are

merely given, whether they are available or not.

Figure 3: Scheme of the event documentation of Bavaria (2005)

In Austria a digital event data base (WLK) has been in use since 2005. In

this data base the event documentation (flood/debris-flow/avalanche)

can even be conducted by non-experts (e.g. mountain rescue service,

fire brigade, etc.) by means of a web-platform. The integration of rock

falls and slides is intended but has not been implemented yet.

More detailed information is recorded with reference to the sources of

information such as informant and documents with their contents,

authors and the availability of the files. An event is located as a point on

an Austrian Map 1:50000 (ÖK 50).

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Figure 4: Scheme of the event documentation of Austria (2005)

In Switzerland a mapping and documentation of events is conducted, if

possible with photographs and films. The up-to-date data are stored

locally in the cantonal data bases as well as in the federal data base

(StorMe).

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Figure 5: Scheme of the event documentation of Switzerland (2005)

In South Tyrol the event documentation is realised by date entry forms,

mapping on the scales of 1:10.000 or 1:5.000, photographs and

additional documents, if available. All the data and documents are filed

digitally and get georeferenced, actually in all three data base systems:

ED30, IFFI and snow avalanche register.

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Figure 6: Scheme of the event documentation of South Tyrol (2005)

Basic principles of DIS-ALP

Methodology

As part of DIS-ALP a standardised data collection is demanded.

Therefore, the work focuses on developing a classification, as easy as

possible, of the known alpine hazards to groups, which subsequently can

be subdivided. This classification is also supposed to be comprehensible

for non-experts. Therefore, it is necessary to reduce the multitude of

existing notions to fundamental terms, which nevertheless enable a

comprehensive description of event types. For this purpose indicators

help to determine translocation processes more in detail. Parameters that

can be expressed by measurement are supposed to be annotated with

the above mentioned MAXO-code.

By defining different investigation standards the extent of information

can be configured. It allows integrating historical sources, determining a

DIS-ALP standard and leaves enough room for investigations going

beyond, which, e.g. for scientists, are a matter of particular interest. It is

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not the task of the event documentation to interpret and analyse the

data.

Figure 7: Structure of the event documentation

The findings can be recorded in check lists or forms. However, it is

important that all spaces that have to be filled in manually have their

correspondence in the data base.

Definitions

For the classification of events and processes various terms have come

into use in the different countries as well as in science. Therefore, within

DIS-ALP, it should be attempted not to break with well-established terms,

but to find common denotations to be able to distinctly attribute events

and processes.

Event

Within DIS-ALP an event is defined as the sum of impacts of one or more

processes, which have a

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• spatial,

• temporal and

• causal

connection and the impacts of which are noticeable, since they exceed

their usual dimension.

In this context an event cannot be equated with exactly one process. In

many cases an event is the addition of several parallel or immediately

successive processes. One initiating process forms the basis for an event.

Events have clearly identifiable starts and ends. An event starts with the

triggering process and ends when the extent of each process involved

lies below its usual degree.

On this top level the events are divided into three groups depending on

the dominantly moved medium. Therefore, the following three groups

can be distinguished.

o snow

o water

o solids

This classification allows a simplified documentation and less effort,

without focusing the documentalist on just one process type from the

start. By this means the loss of certain characteristics and observations, if

these do not apply to a predefined process, can be avoided.

Process groups, processes

According to DIN standard 66201 a process is defined as the

transformation and/or transport of matter and/or energy and/or

information.

Therefore the visual impression of the translocation type can be regarded

as the prime character of a process, which mostly can be perceived by

eye witnesses (and non experts).

Consequently, on a second level, events are grouped according to their

type of translocation.

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Snow event spraying

flowing

Water event running

like debris-

flows

Solid event sliding

falling

Since a documentalist usually cannot observe the type of translocation,

hints given by eyewitnesses are of particular value. Statements made by

observers can be recorded by means of interviews. Information on the

chronological and spatial development of the event is to be collected and

analysed afterwards.

The decisive processes can be deduced from the six process groups.

These are derived from the processes of translocation well known in

practice. However, they are usually differently applied.

As a result the following processes of translocation arise on the third

level (Figure 8):

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Figure 8: Scheme of the classification of processes

Phenomena

The event documentation includes the recording of real facts and

observations, so it refers to something real and comprehensible and

should be free from interpretation and evaluation.

An event which presents itself in terms of a consistently appearing

manner (e. g. physical phenomenon) or spectacle of nature (e. g.

weather phenomenon) is referred to as a phenomenon. Phenomena for

the purpose of the event documentation are events which are observable

and caused by processes, so the processes can be characterised by key

phenomena or “silent witnesses”. Therefore, it is essential that by

means of securing of evidence on site mainly those phenomena are

registered which normally disappear as a result of cleanup and

emergency measures.

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The recording of events from chronicles can also be substantially

improved in its quality, if photo materials or detailed descriptions are

available.

The registration of phenomena is solely made by indicating “yes”, if a

certain phenomenon could be identified or “no”, if the phenomenon did

not occur.

Figure 9: Example of phenomena

Characteristics

Characteristics can be regarded as measurable attributes of phenomena

and thus contribute to quantify processes. Derived parameters are not

the matter of the documentation. They can be identified within the scope

of post proceedings.

Characteristic are recorded as scalar quantities expressed in general SI-

units (e. g. metres, cubic metres) and can have a spatial relation. This is

of particular significance for a connection to a GIS. Characteristics are to

be determined by the MAXO-code to better assess the quality of the

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data. The more attributes about a phenomenon are recorded, the higher

is the information content. With it, of course, the time needed for the

documentation is rising. To reduce the effort, an adequate equipment of

technical devices is necessary.

Collection standards

The DIS-ALP project requires a standardisation of data collection. This

standard can be guaranteed, regarded as the “least common

denominator” of phenomena and characteristics that are to be recorded.

The fundamental documentation, which is based on this standard, allows

a coherent data acquisition and a well structured recording, which can be

used for a continuative and comprehensive analysis of the data. Basing

on it additional information can be collected and filed, depending on the

regional or national demands on event documentation.

In DIS-ALP three different standards for data collection, with a different

scope of content, were defined. A formal interpretation of DOMODIS for

the needs of DIS-ALP was provided by SCHNETZER (2005).

The 3W-standard corresponds to the minimum demands on the analysis

of historical events, whereas the fundamental documentation is based on

the 5W-standard. The 5W+ standard, which is supposed to provide the

basis for detailed analysis, is arranged for experts and scientists. The

demands on documentalists are closely associated with these standards

of data collection.

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Figure 10: Standards for data collection

3W-standard

In general, information about historical events is limited. As a rule, the

further an event dates back, the smaller is the amount of available

information.

Nevertheless, these data should be included into the event chronicle. The

demand for a consistently high standard of documentation is thus

accompanied by the loss of information which can expand the time

frame, even though restrictedly, into the past. Particularly with regard to

long-term strategies like hazard zone mapping and land use planning,

neglecting these data involves a restriction of quality from the beginning

on. However, the effort of utilising historical data must be justified by a

relevant expansion of knowledge. The deciphering and interpreting of a

vernacular vocabulary demand a great effort in the utilisation of historical

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documents. Its value lies in the opportunity to integrate these documents

into a higher platform (e. g. DIS-ALP portal, HANG, StorME, WLK). By

that means substantial information is made easily accessible and

available to a broad public. Defining a “small” standard thus eases the

decision to use a particular historical document. Nevertheless, this

consideration may by no means lead to a general limitation of the topical

documentation or of the utilisation of historical data.

To obtain information the following questions should be answered.

o What happened?

o When did it happen?

o Where did it happen?

Annotation: “what“?

Primarily, information on the predominantly moved substance (event) is

sufficient, so that snow, water or solids should be indicated. If further

information is available the type of translocation (process group) can be

specified.

Annotation: “when“?

The indication of the year is the minimum information needed about the

occurrence and the chronological development of historical events. If

more detailed information is given, also the day can be inferred. Usually

the time of day cannot be found out, but is to be recorded in case it is

given.

Annotation: “where”?

To reference an event a so-called info point has been established,

which is supposed to be approximately in the centre of the damage zone.

Subsequently, a link to several catchment areas can be realised by this

means. This info point will thus be in an area of settlement in most

cases.

If more information is provided, the data can also be recorded. An

approximation to the 5W-standard can thus be achieved.

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5W-standard

The so-called basic documentation according to the 5W-standard is

designed to be conducted by trained persons. It comprises the most

important parameters about the time and the place of an event, the

positioning and a rough description of damage as well as information on

the persons involved in the documentation.

It is of vital importance to chiefly record those phenomena and

characteristics which will be changed or removed by cleanup

measurements. Therefore documentation requires a tight planning of

investigation, a selection of utilities and equipment prior to an event and

a documentalist who is immediately available. It is a key factor to

minimize the time needed for the basic documentation. It is thus

favourable to provide documentalists with checklists, quickly operable

measurement systems and appropriate instruments. Furthermore, it is of

vital importance to train people for the event documentation. To mention

it again, no interpretation of processes is to be made, only the recording

of phenomena and their characteristics.

In the basic documentation the 3W-standard (who, what, where) is

treated much more in detail and a more accurate documentation is

intended. In addition to the 3W-standard the following questions are

dealt with:

o Who made the event documentation?

o How and when was the event triggered off?

Annotation: “who”?

It is an essential element of any documentation to say who has carried

out the investigation. This reference allows drawing conclusions about

the quality of an investigation.

Annotation: “how” and “why”?

The question “how” is supposed to provide information on the method of

an investigation.

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The question “why” includes information on the triggers of an event, e.g.

meteorological phenomena.

For the purpose of the event documentation the question “how” solely

refers to the investigation of phenomena and the specification of their

characteristics.

References to data which are not recorded according to the DIS-ALP

standard are considered as additional information.

5W+ standard

An enhanced documentation of events is less significant than the basic

documentation. In most cases it is carried out by persons who work in

the field of natural hazards and who are highly experienced in the

documentation of events. It will take up days or weeks. Nevertheless, the

emphasis should be put on recording data which is subject to variation.

The enhanced documentation is based on the basic documentation and

thus is a quality check for it at the same time. Again no interpretation is

to be made.

Integration of standards into checklists and data bases

The investigation methods specified above are implemented by forms

and checklists. Forms are focusing on basic parameters and usually give

little room for any additional observation. Checklists can be designed

much more extensively. It is left to national decision makers which

standards of data acquisition are required. In any case, analogue notes

must be easily transferable to a data base.

Therefore, the checklists in the appendix (event reports) merely serve as

a guideline for a uniform documentation of events. They can be

transferred to forms after defining the requirements on the investigation.

Basically, a distinction between different reports, according to the event

(snow, water, solids), is made. A completed data entry form, and thus a

completely recorded event therefore automatically becomes a

standardised report on the observed event.

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To preserve applicability the following three aspects were considered

when the checklists were designed:

o Preservation of objectivity, no statements basing on

interpretations,

o consideration of spatiotemporal conditions for the documentation

of phenomena

o creation of a universally valid design.

As a consequence of the demands on efficient data management, the

digital storing of event reports is indispensable:

o comprehensiveness,

o easy acquisition of information

o limitation of data loss

o prevention of “graveyard data”

The structure designed for the event reports allows a direct matching of

the 5W-standard with the DIS-ALP data base. Based on the methods

presented in this report, a direct incorporation of the information into the

DIS-ALP portal can be guaranteed.

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Checklist DIS-ALP data base 3W 5W

A.1. Basic data - event period [dd.mm.yyyy - dd.mm.yyyy]

Event_start_datetime x x

A.1. Basic data - event period [dd.mm.yyyy - dd.mm.yyyy]

Event_end_datetime x x

A.1. Basic data - event period [dd.mm.yyyy - dd.mm.yyyy]

Event_duration x x

A.1. Basic data - catchment area (official name) Catchment_code x

A.1. Basic data - catchment area (local name) Geographical_name x x

A.1. Basic data - political community Admin_areas x

A.1. Basic data - political district Admin_areas x

A.1. Basic data - internal record number External_documentation_id x x

A.1. Basic data - ducumentalist External_contact_ID x x

A.1. Basic data - organisational unit External_org_code x x

A.1. Basic data - start of investigation [dd.mm.yyyy hh CET]

Investigation_datetime x x

A.2. Investigation type Investigation_type x x

A.2. Investigation method Investigation_method x

A.3. Info point Location_method x

D.1.) Trigger D.1.1.) Meteorological conditions

Event_trigger x

D.1.) Trigger

D.1.1.) Meteorological conditions, additional observations

Event_trigger_description x

E.) Documentation: process group Event_process_group x x

E.2.) Impact E.2.1.) Predominant process type in the mainly affected area

Event_phenomenon x x

E.2.10.) Description of the event in the affected area

Event_description x x

E.2.8.) Deposit volume in the affected area Deposite_volume x x

K.) Registration of damage: buildings Buildings_destroyed Buildings_damaged

x

K.) Registration of damage: traffic and transport Traffic_facilities_destroyed Traffic_facilities_damaged

x

K.) Registration of damage: persons Persons_killed Persons_injured

x

K.) Registration of damage: supply and communication facilities

Supply_facilities_destroyed Supply_facilities_damaged

x

Table 1: Comparison of parameters of the checklist “water” with those of the DIS-ALP data

base for the 3W and 5W standards

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Flow of information and data

Flow of information

Several people with different training are involved in the process of

documentation. However, these people are responsible for the flow of

information and data. Before the actual documentation starts, numerous

people are already involved in the process of notification. Let us assume

that an event is observed by just one witness. If this person regards the

event as unimportant, he or she will not inform anyone but perhaps just

pass it on to his or her circle of friends. If the information is rated to be

more significant, this person will inform someone who he or she

considers to be a suitable addressee for this notification. This can be the

fire brigade, the police, a local councillor or a representative of an

organisation dealing with natural hazards.

From this moment on it is important that the flow of information is well

structured. Finally, just one person has to decide whether an event is

recorded. For this purpose legal and administrative regulations must be

provided, since the event documentation requires resources of personnel,

materials and money. Therefore, the information about an event must

advance from primary contacts to a decision-maker. However, this

procedure must be laid down on a national or regional level.

Decision-makers delegate the documentation to people who have a

respective expert knowledge. Therefore, it is essential that decision-

makers have a list of all persons and companies from which they can

select. It appears to be favourable to fix cost rates in advance.

The documentation on site is followed by the recording of the data into

national (regional) data bases, which is done by the documentalist or by

another person. Results from analyses from the post processing can also

come from a different circle. It is considered to be necessary that the

person who realises the documentation work on location controls the

recorded data in order to avoid any discrepancies and faulty insertions.

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Figure 11: Scheme of the flow of information and data

Reporter

A reporter is someone who has experienced an event at first hand and

who informs a primary contact (organisation or person). A reporter is

thus on site from the beginning of an event. It can be assumed that he

or she has no previous knowledge on the procedure or the contents at

all. A reporter can thus be assigned to the group of “laypersons”. In most

cases a reporter will have good knowledge of the location.

Decision-maker

A decision-maker is a member of a responsible organisation with

respective authority. He or she causes the event documentation to be

made.

Usually decision-makers are not on site. Therefore their information

contains no direct observation. Knowledge of the location cannot be

assumed.

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Documentalist

A documentalist is a person on site who carries out the basic

documentation of an event. The time of arrival at the event location

clearly lies after the beginning of an event, yet as closely as possible.

A documentalist can be assigned to the group of practitioners. It can be

assumed that members of the group of experts (scientists) will take part

in the documentation procedure at a later date.

A skilled documentalist on site has good knowledge on the location and is

able to record the most important characteristics of an event by using

data entry forms (checklists). If he or she has no knowledge on the

location it will be compensated by a close contact to affected people,

witnesses, labourers and organisations working at the location.

Documentalists are not involved in rescue work or cleanup efforts and

can thus work independently.

Preparatory measures

Preparatory measures contain the following procedures:

• setting up of report structures

• regulation of competence

• integration of the event documentation into local relief organisations

• quick availability of skilled personnel

• to organise trainings

• quickly available material (checklists, forms, maps)

• quickly available facilities for the recording

• easily manageable portals for data bases and the web

Order of priority of the investigation

To guarantee a perfect procedure of the documentation and to gain a

maximum of information, priorities must be assigned for the

investigation. Since the documentation proceeds at the same time as

cleanup efforts, however of less importance for the crisis management,

recordings on site will at first be restricted to the essential. However, first

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investigations in the areas of activation and translocation can be made

comparatively freely, just as interviews can be carried out. Somewhat

later the damage zone can be documented in detail without any

difficulties.

Investigations corresponding to the 5W-standard are usually not started

until the end of cleanup efforts.

Figure 12: Scheme of the order of priority of investigations

Investigation phase A

o Recording preferably before the beginning of cleanup efforts

The documentation begins in the damage zone, since emergency

and cleanup measures are usually initiated in this area. Only

phenomena and characteristics that can be observed during or

shortly after an event are to be recorded, since these are altered

or deleted by cleanup and emergency measurements.

Characteristics can be fixed to quantify them in a later phase of

the investigation.

In this report it is assumed that field work in potentially

dangerous areas is only carried out with adequate safety devices.

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o Recording parallel to cleanup efforts

It is favourable to have interviews parallel to cleanup

measurements to get some clues on the event triggers and to

examine photo and video materials. Furthermore, in most cases

the catchment area (i.e. the activation zone) and the

translocation area can be inspected as well as observable

phenomena and their characteristics can be recorded without any

difficulties.

Above that, the prevailing process type of the damage zone can

be determined and the damage can be recorded.

o Investigation after the ending of cleanup efforts

The interaction of a process and protective structures can best be

described after the ending of cleanup efforts, since in most cases

the original condition appears again. In this phase of

investigation interviews are analysed and the answers covered by

them are evaluated. Characteristics which were unapproachable

before the cleanup efforts can now be quantified.

Investigation phase B

Investigation phase B is subject of detailed investigations (5W+

standard). The catchment area can be inspected completely and the

situation can be presented in an investigation report. Similarly, additional

characteristics of the activity zone and the translocation area can be

measured in order to analyse them in the post processing.

Investigation phase C

Data which is collected independently from the event documentation by

other organisations are partly only available for the event documentation

after a check on the raw data. This particularly applies to hydrographical

and meteorological data. In the same way it will take some time to

develop orthophotographs, so that these data cannot be included until

the final stage of the documentation. This activity can be done in an

office for the most part.

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The post-processing, the analysis and interpretation of the data, can

be started with investigation phase B.

Flow of data

The flow of data begins with analogue notes on data entry forms or

checklists. Digital sources of investigation phase A mostly consist of

photo and video material. These data can be filed in structured archives

or stored digitally to be available for a later analysis. Digital collection on

site is especially advisable to record characteristics, whereas a connection

to a GIS is favourable. Respective tools are to be developed.

After the return of the documentalist the data is entered into the national

(regional) data bases. They can also be directly input into the DIS-ALP

portal by means of data upload (see chapter “bulk insert of individual

data”)

The data backup and administration takes place on a national (regional)

level. It must be kept in mind that these data mainly provide a basis for

those people who are locally assigned with the protection from natural

hazards. The collected data must be provided to these people in an

adequate form.

Technical guideline for event documentation

Basic cartographic considerations

Cartographic representation of natural disaster events has to fulfill a variety of requirements, and

these become rather specific when taking the perspective of event documentation:

o intuitivly understandable

o GIS and CAD implementable

o easy to draw manually (in the field !)

o internationally understandable

o scale independent (as far as possible)

o directly representing natural processes

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Considering these requirements a set of rules was defined as guideline:

o Form of symbols should reflect properties of processes

o Color of symbols should distinguish the processes themselves

o Symbols must be easily recognisable against different

backgrounds (e.g. color or black/white aerial photos,

topographical base data)

In more detail color guidelines for process description was outlined:

Figure 13: Color representation rules for different processes

Symbols were defined in detail distinguishing point, line and area

features, differentiated by

o Type of process

o Process phase (process start, transport, accumulation)

o Damages

o Background map (colored vs. non-colored, scale)

Figure 14: Example for linare features differentiated by process phase

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Advantages and disadvantages of symbolisation methods were discussed

in detail with examples of processes pictured against maps of different

background information density, color and scale. This allows for a clear

choice of representation method adapted to requirements of digital

mapping, field work and end-user communication.

Figure 15: Example of processes mapped against colored topographical map at small scale

(1:50.000)

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DIS-ALP Knowledge Base

Knowledge formalisation

The thematic oriented work-packages of DIS-ALP have produced a lot of

information useful for practical purposes in the context of disaster

documentation and beyond:

o Methodology work-package produced detailed classification and

characterisation of alpine natural disaster processes and related

phenomena;

o In the same work-package documentation procedures and

related organisational issues were elaborated;

o Process and phenomena related information were reconsidered

in parallel from a practical point of view in work package

instruction and amended with illustrations and graphics.

These results have been produced as paper reports and are usually – in

comparable project environments – formalised only as glossaries. In

DIS-ALP tbe results listed above were considered for an additional

complementary way of formalisation. A more formalised representation of

knowledge provides several advantages, compared with classical paper

work; among others:

o Automatic processing of knowledge when knowledge is

formalised standard conforming;

o Integration with other sources of formalised knowledge;

o Reasoning capabilities, providing integrity checks of formal

definitions and support for classification of terms.

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Figure 16: Development of formalisation presentations (adapted after METOKIS

D8)

After an attempt to start formalisation with a classical Thesaurus as used

e.g. in UDK (UmweltDatenKatalog) in Germany the deficiencies of this

approach in comparison with ontologies became evident:

o Low degree of formalisation (ontologies provide formalised

definitions of terms with restrictions and preoperties, whereas a

Thesaurus provides only free text scope notes);

o No reasoning capabilities;

o Promising current and future application opportunities when

using ontologies (query support, information and database

matching, …)

DIS-ALP knowledge as ontology

After deciding to use ontologies as formalisation option a solution for

integration into an existing pre-defined and widely accepted ontological

base was thought. Detailed investigations showed that no adequate

formalised knowledge was available in the thematic domain of DIS-ALP.

In contrast well established ontologies had been developed to deal with

more basic concepts (terms), which were recurring and could be used in

many different thematic fields. These ontologies are usually referred to

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as “top-level” ontologies. They start with a top-down definition of terms,

beginning with the most general terms.

As top-level ontology DOLCE (http://www.loa-cnr.it/DOLCE.html) was

choosen, which was initially defined in a Europea research project and is

continously being further developed and refined for different thematic

uses (e.g. legal knowledge). The most important terms defined in DOLCE

and used within the DIS-ALP ontology as link to DOLCE were

o Process

o Phenomenon

o Social role

o Task

Based on these terms the most relevant properties and restrictions were

inherited to DIS-ALP terms and could be thus re-used and refined,

avoiding redundant definition of base terms.

DIS-ALP ontology example

The DIS-ALP ontology was developed using Protégé as tool and OWL

(Ontology Web Language) as representation option.

Figure 17: Example of graphical representation of terms and their basic relations

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DIS-ALP ontology use

Direct use of the DIS-ALP ontology is provided via the DIS-ALP web

portal (portal.dis-alp.org) and is described in detail in the respective

chapter.

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Documentation support

New tools for geo-hazard documentation in the field

and by remote sensing

Introduction

The post-event survey of mountain disasters greatly benefits from the

use of up-to-date technologies. Using modern surveying tools contributes

to fast execution and high accuracy of field measurements and facilitates

the efficient acquisition of data in digital form, easily available for further

analysis. Despite of the utilisation of state of the art field surveying tools

mainly based on GPS- and advanced computer technologies, remote

sensing techniques, due to the great variety of available sensors and

image products can contribute substantially to process analysis, post-

event documentation and disaster relief.

In the context of the DIS-ALP Project, some experiences have been

carried out on the use of different tools that can be employed in the

survey of natural disasters in mountainous areas, additionally the

applicability of remotely sensed information was evaluated with particular

regards of floods and debris flows and other mass movements.

Considered tools are:

• GPS techniques for mapping areas affected by flooding

and sediment deposition

• Mapping techniques with integrated systems of laser

rangefinders and GPS

• Mobile devices for field mapping (Tablet PC, PDA)

• Aerial LIDAR surveying for an enhanced representation

of topography.

• Images aquired by airborne and spaceborne remote

sensing sensors showing different characteristics and

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mapping capabilities in the context of geo-hazard

documentation.

Basic Principles - Experiences

Basic principles of the Global Positioning System (GPS) can be deemed to

be sufficiently known. Here we shortly remind that GPS is a worldwide

radio-navigation system formed from a constellation of satellites and

their ground stations. GPS uses satellites as reference points to calculate

positions. The basis of GPS is triangulation from satellites: to triangulate,

a GPS receiver measures distance using the travel time of radio signals.

To measure travel time, GPS needs very accurate timing; along with

distance, it is also necessary careful monitoring of the orbits in order to

know exactly the position of the satellites in space.

Laser rangefinders are binoculars with an integrated reflectorless

distancemeter, a digital compass and a digital inclinometer. Current

systems can be connected to GPS-devices, enabling the user to map

inaccessible features or remotely located objects from distances up to

1500m (or 4000m, depending on the model). This allows the user to

choose positions that are safe or that provide favourable GPS signal

conditions.

Rugged Tablet PCs and PDAs offer a digital alternative to classic mapping

techniques. Reproducing the traditional method allowing a user to draw

features on a map with a pen the use of these mobile devices typically

requires little training and is easily comprehensible even for personnel

with limited technical background. In connection with wireless data

transmission these systems can be used to acquire and deliver relevant

information close to real time.

Remotely sensed images are acquired by a broad range of sensors

mounted on airborne and spaceborne platforms. Most of the systems are

“passive” i.e. they are mapping the energy/waves radiated by the sun

and reflected off the object on the ground (cameras; panchromatic,

multispectral and hyperspectral scanners). Despite of topographic or

location information, the wavelength-dependent reflection/absorption

features of the materials on the ground are portrayed. Using this

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information, features present in the remotely sensed imagery can be

delineated and classified (e.g. alluvial fans, flood plains). Additionally

Synthetic Aperture Radar (SAR), an active system transmitting and

receiving microwaves, is of special importance for the documentation of

geo-hazards due to its all-weather capability. Using wavelengths of over

2 centimetres, SAR is capable to penetrate clouds and even rainfall. SAR

data is frequently used as a complimentary data set to “classical” remote

sensing information due to the fact that radar is mainly acquiring

information on the physical and electrical properties of the objects (e.g.

surface roughness, moisture), what makes it a powerful tool for the

delineation of flooded areas or areas prone to mass movements. New

SAR technologies, like Interferometric SAR, allows for the measurement

of subtle small movements and therefore for the mapping of mass

movements, glacial features or subsidence. Slope instabilities are

evaluated calculating slope inclination maps, coherences and phase shifts

present in InSAR data. Generally remote sensing techniques can bring

new dimensions to hazard documentation because on the one hand

synoptic and detailed disaster information can be extracted from archives

containing different imagery, dating back approx. 100 years in the case

of airborne information and dating back to the early 1960tiers in the case

of spaceborne imagery. On the other hand event information can be

retrieved which cannot bee seen by the human eye, but is contained in

data mapping the visible to infrared and microwave range of the

electromagnetic spectrum.

LIDAR means Light Detection and Ranging, indicating a laser distance

ranging apparatus (sensor) without any reference to the platform

(terrestrial, aerial, etc.) in which the sensor is mounted. When focusing

on laser scanner apparatus mounted on helicopters or airplanes, it would

be more appropriate to refer to airborne laser altimetry (ALA) or airborne

laser scanning (ALS) technology. In ALS, a laser scanner is mounted on

an aircraft (airplane or helicopter) and is connected with a differential

global position system receiver (DGPS) to determine the absolute aircraft

position, and an inertial navigation system (INS or inertial measurements

unit IMU) capable of defining the pitch, roll and yam (heading) of the

aircraft (Fig. 1). In this way, by connecting a differential GPS with a very

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sensible INS unit, the absolute position and the 3D orientation of the

aircraft in the space and consequently of the laser scanner apparatus can

be known in every time interval.

Figure 18: Schematic overview of Airborne Laser Scanning technology

Implementation – Field trials and Results from the evaluation of the applicability of modern remote sensing techniques

Several tests have been carried out in the field for comparing the

performances of different GPS systems in the survey of floods and debris

flows in alpine torrents. The instruments used range from low-cost

receivers to rather expensive topographic GPS: the following systems

were used:

o Tom Tom Navigator 3 wireless GPS linked to a palmtop HP iPAQ

h1940 Pocket PC;

o HOLUX GPSlim 236 wireless GPS linked to MDA-Pro Palmtop

o Trimble Pathfinder Pocket Receiver linked to a palmtop CompaQ

IPAQ palm PC;

o Trimble GEO Explorer;

o Leica GPS System GS20

o Leica GPS System 500 model SR 530;

o GEOTOP TOPCON Legacy E.

o Leica Laser Locator

o T-Mobile MDA Pro Palmtop Computer

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o Xplore iX104C2 rugged Tablet PC

The test areas were selected on the alluvial fans of some torrents of

Eastern Italian Alps and some easily recognizable features in the

Wienerwald region 20km west of Vienna/Austria; the test consisted in

walking the same path using different GPS receivers or mapping them

using additional devices. The performance was evaluated by considering

the differences between the tracks surveyed using various GPS receivers

and comparing them with ground “truth”; an analysis of PDOP (Point

Dilution of Precision) values was also carried out. The main results are

summarised below.

TomTom Navigator 3 wireless GPS was designed as a receiver for in-

car navigation. Its use in the present study was aimed at evaluating the

possible performance of a simple, low-cost instrument in post-event

survey of torrent disasters. An advantage of TomTom Navigator 3

wireless GPS is the blue tooth connection with a Palmtop PC: this avoids

possible problems due to the presence of a cable connecting the receiver

to data acquisition system. The results of the tests indicate a low

accuracy of the measurements. Although the loss of accuracy within

forest stands and in urban areas is a common problem of GPS, TomTom

Navigator 3 wireless GPS is more sensible than other instruments to

these disturbances. This receiver does not permit differential correction.

For these reasons, the use of this type of instruments should generally

not be recommended in the survey of mountain disasters.

The HOLUX GPSlim 236 represents the newest generation of GPS-

consumer devices and is equipped with the SIRF Star III GPS-Chip.

During the tests the GPSlim 236 produced very robust and reliable

results. Under difficult conditions (heavy foliage, signal reflections) it

even displayed higher robusness than professional GPS solutions like the

Leica GS20. Advantages of the GPSlim 236 are the wireless Bluetooth

connection, the changeable battery and the small size. The main

disadvantage of the GPSlim 236 is that it is not EGNOS/WAAS enabled.

GPS Trimble Pathfinder Pocket Receive: linked to CompaQ IPAQ palm

PC. Some observations on the use of this instrument have been

presented in paragraph 2.1.1. The instrument is handy and its

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performance is generally adequate for post-event surveys when high

accuracy in the measurement of elevation is not required. It can offer a

good compromise between cost and performance. Possible drawbacks

are the cable connection between the receiver and the palmtop PC, the

terminal is not waterproof and is rather sensitive to shocks.

Rugged case and sunlight display make the Trimble GEO Explorer very

suitable for use in the field; the performance of this instrument seems to

be satisfactory for post-event surveys in alpine torrents.

Both topographic GPS systems used in the tests (Leica GPS System

500 and GEOTOP TOPCON Legacy E) are suitable for post-event surveys

of mountainous disasters. The use of Glonass satellites is a valuable

characteristic of GEOTOP TOPCON Legacy E.

The Leica GS20 GPS is especially useful when used combined with the

Leica Laser Locator. This system enables the documenting personnel to

map features in inaccessible or dangerous environments from the

distance. Due to the large range of the Laser rangefinder (up to 1500m)

the system enables the user to perform mapping tasks in a highly

productive manner. There exists a completely streamlined process from

preparatory operations to data acquisition, postprocessing and data

export in common exchange formats like ESRI-shapefiles or dxf-files.

The main drawbacks of the system are the high prize and the fact that

the quality of the mapping results depends heavily on the accuracy of the

determination of the local declination value. This deviation of geographic

and magnetic north varies significantly in space and time. Other sources

of error are all kinds of magnetic fields that may influence the

determination of the azimuth. Professional GPS-devices like the Leica

GS20 are normally equipped with a metal ground plate shielding the GPS

receiver from signals reflected from the ground. Although this feature

enhances the quality under favorable conditions it results in the earlier

loss of the GPS-Position in difficult environments compared to systems

without signal reflection shields.

The tests of the Xplore rugged Tablet PC and the MDA Pro palmtop

computer showed that both types of devices have the potential to

increase the productivity in post event documentation. The necessary

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efforts of preparatory operations like the production of mapping material

and post processing tasks like digitizing can be reduced significantly.

There exist out of the box solutions for wired an wireless scenarios for

the Tablet PC as well as for the PDA. In the case of UMTS/GPRS

connectivity it could be shown that the user experience of thin clients on

PDAs getting all the data over the wireless connection is acceptable.

Advantages of the Tablet PC are a user experience similar to the desktop

PC and high storage capacities enabling the user to carry vast amounts

of data in the field. Drawbacks are the weight of 1.5 to 2kg and the high

price. Advantages of the PDA are mainly the small size and weight and

the high integration factor. Many systems are integrating mobile phone,

camera, GPS and PDA. The main drawbacks of PDAs are the reduced

speed, the reduced stability, the small display and the high energy

consumption compared to the battery capacity (especially when wireless

connections are used).

The analysis of LIDAR data carried out in the DIS-ALP Project regarded

two test areas of the Eastern Italian Alps. One product is represented by

high-fidelity filtered dataset (in which the filtering of non bare-earth

characteristics was improved manually) reporting ground elevations of

the Agozza basin (Figure 19), located in the Friuli Venezia Giulia Region.

This dataset is available thanks to the University of Udine, which

collected data in relation to the European project INTERREG IIIA Phare

CBC Italy-Slovenia – Action 3.2.4. The surveyed area, is characterized by

very complex topography with relevant changes in elevations, ranging

from 900 and 2500 m a.s.l within an area of about 6 km2. Most of the

basin is characterized by a dense forest cover.

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Figure 20: The second LIDAR product consists of a raw points cloud

representing surface heights (bare-earth, buildings, trees, etc.) of the

partly urbanised Predazzo area (Province of Trento). The surveyed area

includes the small town of Predazzo (Province of Trento), located on the

alluvial fan of the Travignolo Torrent, a stretch of the valley of the

receiving stream and the lower parts of the slopes. This area is

characterized by dense vegetation cover on mountain slopes. The

topography is moderately rugged and the elevation ranges from 900 to

1500 m a.s.l.

Figure 19: a) Orthophoto of the Agozza area, the perimeter of the basin of interest is

outlined; b) 3D terrain model of the Agozza basin (units in meters).

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Figure 20: a) Shaded relief map of the digital surface model of the Predazzo area; b) 3D

terrain model of the Predazzo area (units in meters).

An exploratory analysis has been carried out in order to devise tools

(statistical indexes and graphical utilities) useful for acquiring familiarity

with aerial LIDAR data set. A useful procedure, especially when using

filtered data, is to calculate elevation points spatial density using a

moving windows approach. In this way, it is possible to analyze how

LIDAR points spatial density changes along the surveyed area and

depending on the ground cover type. Superimposing spatial density maps

to orthophotos enhances the spatial distribution of data. These tools

make it easy to detect areas of poor coverage, choose the correct radius

for interpolation and detect pattern in data spacing generated by the

survey procedures. When using filtered dataset, it is worthwhile to

analyse, for selected locations, elevations data in correspondence with

buildings, water surfaces, and streets to check for failure in filtering

algorithms and lack of data due to target reflectance. Moreover, it has

been noted that some errors/artefacts can be correctly identified by

analyzing preliminary digital surface models. As an example, shaded

relief maps can be superimposed to orthophotos.

The main operation with LIDAR point data is to derive digital elevation

models. Considering the high density of spatial sampling and the extent

of the modelled area, simple interpolation algorithms such as

triangulation , natural neighbour, and inverse distance weighted (IDW)

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give good results. Clearly, attention should be paid in areas with lower

point density where triangulation could generate artefacts and a natural

neighbour algorithm could perform better. These algorithms are not

really computer intensive. If the area of interest is small and a high level

of accuracy is required, interpolation tools like splines or geostatistical

tools (various form of automated kriging, in particular local kriging) could

grant better results (although they are more computer and user

demanding).

Hardware and software issues have also been considered. The large size

of LIDAR data files implies that adequate storage capacity (hard disk,

DVD media reader-writer) is required on PC. It also important to

remember that the graphic card is essential to visualize data quickly and

to the 3D display of the highly-detailed DEMs created by interpolating

LIDAR points. All the calculations and manipulations of data were

performed on a Laptop computer, running a 2 GHz Celeron processor

with 640 Mb of RAM. Compared to machines currently available, with 3.5

GHz processor and 2 Gb of RAM, the PC used is evidently less powerful.

The tests carried out in this study show that the processing of LIDAR

data for small areas, such as those corresponding to alpine torrents and

alluvial fans, can be performed also by means of low-cost PCs available

also for junior professionals and technical offices of local administrations.

Because of the large size of the files, the visualization and editing of

LIDAR data files may prove difficult. Word processors like Notepad,

Wordpad, Microsoft Word, Openoffice Writer do not work properly with

such large files: the editing becomes tedious and sometimes causes the

code to crash. Word processors like “Textpad” (in MS Windows) or

“Emacs” (in Unix – Linux systems) perform better. Problems also arise

when using worksheet programs like MS Excel or Openoffice

spreadsheet. For example, Excel limit has a limit of 65.000 rows, which

are obviously not sufficient to manage LIDAR data. A better choice could

be the Surfer worksheet which, depending on the resources of the PC

used, can manage up to 1 billion rows. Nevertheless, you have to be

aware that even if it is possible to load data in a worksheet like Surfer,

the editing and the saving of the modified file could be a long task. To

perform some simple file editing (i.e. truncate decimal digit, change the

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file from space delimited to comma delimited, deleting columns, etc.) it is

more efficient to build small custom codes. The storage of points cloud

files becomes easier using database tables (MS Access, Mysql, Postgres).

The evaluation of the applicability of modern remote sensing techniques

showed that there is a great variety of data usable for hazard

documentation. In the last years the accessibility of remotely sensed

image information improved substantially. Most of the data archives can

be accessed directly by internet and the relevant information, like ground

coverage, image quality, date and time of acquisition etc. can be

retrieved easily and quick looks of the images can be displayed directly

on the screen. “Historic data”, depending on the provider, is available

within some days, actual data – especially in the case of major disasters

– within hours (e.g. UN charter “Space and Major Disasters). Image data

showing a very high ground resolution is in the meantime not limited to

the “airborne sector” but can also be provided by spaceborne platforms

like FORMOSAT (2 m), EROS-A (1,9 m); IKONOS (1 m), ORBVIEW-3 (1

m) and QUICKBIRD (61 cm). Images taken by classical camera systems

and digital cameras as well as images acquired by panchromatic and

multispectral scanners are in most of the cases provided in formats (e.g.

tiff, jpg, ecw) which can be handled and referenced by standard mapping

software already used in the sector of natural hazard prevention and

control (e.g. AUTOCAD, ARCGIS). Only when using Synthetic Aperture

Radar (SAR) images and hyperspectral information special remote

sensing software packages like Erdas/Imagine, ENVI etc. must be used.

Even very high resolution satellite imagery can be purchased on a

reasonable price. IKONOS data sells at 20 to 30 US$ per Sq. km,

QUICKBIRD data at 16 to 45 US$ per square km depending on pre-

processing level (e.g. orthorectified) and mode of data handling and

delivery (e.g. “rush tasking”).

The evaluation of the literature and an internet search showed that

remote sensing techniques are already frequently used in hazard

documentation. The documentation and monitoring of flood events is

mainly done by using time series of high resolution airborne imagery, by

the interpretation of high resolution spaceborne sensors operating in the

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visible to near infrared range and by Synthetic Aperture Radar (SAR)

techniques. Mass movements are monitored using “classical” sensors as

well as state of the art methods of Interferometric SAR (InSAR). InSAR is

also used for snow and glacier mapping. Up to now multispectral and

hyperspectral information is in only very view cases used in hazard

documentation although these data would be very well suited for the

delineation of alluvial fans and for the classification of sediments and

vegetation cover.

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Figure 21: Example of an inquiry for high-resolution QUICKBIRD imagery of the Danube-

March area in eastern Austria using the archive tool provided by Digitalglobe

(www.digitalglobe.com).

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Recommendations

The results of field experiences make it possible to outline some advices

regarding the use of GPS in just-post event survey of mountain disasters.

Topographic GPS systems are quite expensive. By contrast, portable GPS

are rather cheap and an office/department can buy several instruments

for simultaneous use in different sites: this is important when limited

time is available for post-event surveys (e.g. because of the removal of

sediment deposited on alluvial fans). The main advantage of topographic

GPS is their precision in the measurement of elevation, which allows GPS

to replace standard topographic surveys for many applications. In post-

event observations of mountain disasters this regards, for instance, the

changes of cross-sections and longitudinal profiles of channels and the

assessment of eroded and deposited sediment volumes. As far as the

execution times are concerned, if the tracking-log mode is activated,

topographic GPS require the same time as portable GPS, but ensure a

much higher accuracy. The only difference is the initial time required for

installing and setting up the master receiver, which can be estimated to

about 20’. A practical limitation in the operation of topographic GPS in

the survey of mountain disasters could consist in the need of a safe place

for the installation of the antenna used as Master receiver (this might not

be easy in the emergency phase). Acquisition of the coordinates

corresponding to fixed reference points (Mess Punkt, Verm Punkt) is

recommended because it provides a check on the accuracy of GPS

surveys and allows them to be superimposed on previous topographic

surveys. Preliminary observations of the area to be surveyed and a

careful choice of the path make the GPS survey faster and contribute to

its success. Topographic GPS systems make it possible to carry out

complete topographic surveys: the assessment of deposited volumes is

thus possible by comparing the surfaces surveyed before and after the

event. It is necessary that the ellipsoidic elevation of the studied area

(e.g. from aerial laser scan) is available for before-event conditions.

When using portable GPS, no reliable measurement of elevation is

possible. It is possible, however, to survey the horizontal coordinates of a

number of points within the deposit and assign the thickness of the

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deposits as an attribute. A digital model of the thickness of deposits can

then be implemented, thus permitting an estimate of volumes deposited.

With regard to the use of LIDAR data, some considerations are presented

hereafter.

o Many factors influence the success and quality of a LIDAR

survey. For this reason, when acquiring LIDAR data, it is

necessary to obtain all the survey specifications. In particular,

the accuracy of the final LIDAR product should be evaluated

separately for each main land cover type characterizing the

surveyed area. Errors can arise also in the filtering process and

special care should be paid in using LIDAR data in forested area.

o The quality of the analysis and processing of LIDAR data

increases when supported by other data sources (for example

orthophotos or cartography) and by manually edited data.

When carefully filtered, LIDAR data permit to build high resolution and

accurate digital terrain models with relatively fast survey also in forested

area. These detailed digital elevation models could be then analysed by

means of various techniques (visual analysis of shaded relief maps, 3D

visualizations, calculation of morphological and spatial variability indexes,

etc.) and allow to perform quantitative comparisons between pre-disaster

and post-disaster digital terrain models characterized by the same

accuracy and resolution.

The evaluation of the applicability of remote sensing data for the

documentation of natural hazards showed that suitable data in the

meantime can be easily accessed via Internet, purchased at reasonable

prices, and using standard formats can easily be integrated in GIS and

mapping software like AUTOCAD and ARCGIS. Considering the great

advantages of remotely sensed information for hazard documentation

and mapping purposes they should be used more frequently within

hazard documentation procedures and post-event documentation.

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Instruction

Introduction

An important basis for homogenous results of the documentation process

is the preparation of easy to use common instruction materials. These

materials were developed as portable field guides.

Field Guide

This manual for the documentation of natural disasters was designed to

be a handout for courses as well as a reference book for field work.

Introduction includes organisational principles and elements of an optimal

documentation.

Modules of an optimal documentation as defined in the field guide are:

o Forms and check-lists in order to ease standardisation

o Documentation of background information (geography,

meteorological conditions, damages, protection works)

o Maps, drafts and photo documentation

o Level of detail of documentation (as defined by requirements of

contracting authority)

o Field equipment

The main part of the field guide is dedicated to the most important

phenomena of floods/debris flows, landslides/slope-type debris flows,

rockfall processes and snow avalanches. They are shortly are explained

and illustrated with numerous photographs and drawings.

This field guide complements from a practical point of view the results of

WP methodology. Phenomena or characterised in a standardised way so

that field work can easily be accomplished after a short instruction phase:

o Introduction to phenomenon

o Characteristics of effects

o Visible effects and their relative locations

o Documentation content for each category of visible effects

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Figure 22: Example of phenomena documentation description of field guide

Short description of phenomenon

WHAT should be documented

HOW does it happen

Example photographs

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Projects in schools “Dealing with natural hazards”

Introduction

A part of the project DIS-ALP focuses on the informing and sensitizing of

the public in regard to natural hazards, affecting the everyday life in the

Alps.

In this context the Department of Water Protection of the Autonomous

Province of Bolzano / Southtyrol is keen on acting towards sensitisation

of the young generation. Projects in compulsory schools and high schools

shall help to understand the necessity of protective structures, to outline

the ever remaining risk and to communicate a wise dealing with natural

hazards.

Generally it is not easy for school-outsider, as for example for officers,

civil servants or specialists, to work out an advisable and exciting

program indicated for students dealing with such a highly specialized

topic. This also or especially applies to the topic of alpine natural

hazards.

In the framework of the EU-project DIS-ALP in connection to the work

package public relations most of the attention was paid to this difficulty:

in order to establish the right approach of students with this topic we

decided to carry out with them several actions themed „Dealing with

natural hazards”. From these experiences best practices could be derived

and implemented into a teaching concept indicated for students.

Principles of working with elementary and high school students

The transmission of basic knowledge and demonstration of practical,

handy examples should help the students to have a better insight into

the topic of natural hazards. Since there was not given much time for

every school class, every action should have something special,

impressive and unforgettable”! Therefore it was important to elaborate a

special teaching unit.

On designing the teaching units and single actions, the different

principles were adopted depending on the school-type:

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o Working outdoor by using all senses. The receptivity and capacity

of understanding new topics shall be reinforced and increased by

physical and mental impressions.

o Avoid too great number of students

o Playful and funny approaches to the topic, playful learning

o Designing the teaching units close to reality and practice

o Pick up existing knowledge

These were the followed principles. Their weighting was quantified

differently action by action.

Figure 23: Playful and funny approaches to the topic, playful learning: generally known

games have learning targets, which can easily be adapted to the specific topic: Students

tinker a „natural-hazard-dice“

Excursion on half a day with elementary school classes

During an excursion lasting half a day to the debris flow “Wieser Lahn” in

Jenesien/Nobels (Southtyrol), impressions of the formation of our alpine

landscape have been conveyed to the students. By analyzing the

landscape, the students realised, that our surrounding is in a natural

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permanent transformation process. By examples on site, the students

understood how human beings protect themselves from natural hazards.

The students learned in a playful way how to observe and interpret

traces and signals of the nature. In that way, the students learned to

respect and understand the nature. Man can protect himself from natural

hazards up to a certain degree, but there is no total protection.

Teaching unit with selected high school classes

Short insights into the theoretical basics of natural hazards and risk

management have been provided to the students. In order to create an

interesting teaching unit, realistic exercises have been worked out, where

the students could try to recognize the different hazard types by

themselves and during a role play they also could reflect how to deal

with natural hazards in populated areas. These exercises provided a

connection from the theory to the practice and called on the students to

think logically and observe everything in detail also outside of the school.

Outlook

The collected experiences from the different actions at the compulsory

and high schools showed, that the young generation is absolutely

interested in this topic and that a sensitization to these complex problems

can be achieved. The schools are engaged in collaborating also in the

future with experts and specialists from the sector. Especially the

teachers were interested in collaboration and asked for an advanced

training. However it has also to be mentioned that in order to provide a

sustainable sensitization, the topic has to be fully integrated in to the

teaching program of the schools. Thereby the key points vary depending

on the type and level of schools.

For this reason the Department of Water Protection (Autonomous

Province of Bolzano) envisages the elaboration of a guideline together

with the teachers and school authorities. This guideline should show how

to definitely anchor this topic into the course of instruction of the schools

and which are the right methods to adopt and key points to introduce.

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Implementation

Introduction

The assessment of natural hazards consists in an objective and

methodologically sound analysis of potential hazardous processes

(Heinimann et al. 1998). The assessment of potential hazards requires

the evaluation of former and the prediction of future geomorphologic

processes. Thus, potential hazards can be identified and localized on the

basis of former events, on the basis of the terrain analysis and by means

of process simulation models (Kienholz et al. 2004). The im-pact of

former events can be assessed on the basis of the analysis of silent

witnesses (Aulitzky 1992) or on the basis of the analysis and evaluation

of historical documents and notes. The in-formation about former events

is collected and documented systematically over long-term periods in

appropriated databases (event cadastres). Core elements of an event

cadastre are particulars about the type of a natural hazard event, about

the date and course of the event, about the locality, about socioeconomic

consequences and damages, about the management during the event,

about the weather and atmospheric conditions before and during the

event and about the observer. An event cadastre usually stores only

objective facts about former events and does exclude interpreted data

(Heinimann et al. 1998, Hübl et al. 2002). The interpretation of this

objective data occurs in the context of hazard assessment.

Hazard events in the Alps have been documented systematically and

stored in databases since the 1970ies. For many regions and basins,

long-term observations of precipitation, temperature, discharge or other

environmental parameters are not or only in a moderate extent available

for the use in hazard assessment. Furthermore, in the observation

periods extreme events could only rarely be observed. Or, series of

measurements often show data gaps due to the destruction of the

measurement instrument during extreme events. Thus, hazard

assessment based only on measured data can lead to false estimations.

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In these cases, systematically documented historical natural hazard

events can be a valuable enhancement of the existing data needed for

the hazard assessment (Barnikel 2004).

In this report, historical events are defined as natural hazard events

dated before the beginning of the systematic documentation and

compilation of natural hazard events in specific databases. From silent

witnesses (after Aulitzky 1992) or prehistoric natural hazard events,

historical events are distinguished by a written or unliteral

documentation. From recently documented events, historical events are

differentiated by a non-systematic documentation and archiving process.

Compilation and documentation of historical natural

hazard events

Procedure for the compilation and documentation of historical natural hazard events

Within the framework of Dis-Alp, different studies fort the compilation

and documentation of historical events were realized by the participants.

In the Free State of Bavaria, a state-wide research of historical

documents with information about natural hazards in the archives of,

local authorities (Water Management Offices, communities) was made in

the Bavarian alpine region.. The information was stored systematically in

a database. In the federal state of Salzburg, historical natural hazard

events were collected and stored systematically also state-wide. In the

Autonomous Province of Trento, the triggering conditions, the

geomorphologic effects and the produced damages of the large debris

flow event occurred in the Chieppena Torrent on November 4th, 1966

were analyzed. In the Autonomous Province of Bolzano South Tyrol, a

debris flow event in the Tinne Torrent occurred on August 9th, 1921 was

reconstructed and a chronology of historical events in the Vipiteno Basin

and Bressanone Basin was compiled. In this report, the methods used in

these studies are summarized and synthesized. For a complete citation of

these studies see chapter “Resources”. All of these studies incorporate

the following procedure:

o Definition of the objectives of the study

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o Research for historical documents − archives

o Interpretation of historical sources and extraction of the relevant

information

o Systematic processing of the information and compilation in the

specific database

o Description of the results

Definition of the objectives of the study

The amount of time needed for the localization of historical sources and

the choice of the method used for the reconstruction of historical natural

hazard events depends on the defined objectives of the study. Inversely,

the objectives of the study are determined be the level of de-tail of the

existent sources. Some sources allow only a chronological listening of

roughly documented historical natural hazard events in a delimited area,

whereas other sources allow a de-tailed reconstruction of a certain event.

For the choice of the method and the adaptation of the expenditure of

time to the expected benefits of the research, the definition of the study

objectives and the delimitation of the study area is required. Regarding

the spatial aspects, historical research can be made on regional scale

with little detail for a wide area or on local scale with more detail for a

closely delimited area. Regarding the considered time-scale, historical

research can be focused on the compilation of a chronology of events or

on the detailed documentation of one single event. Thus, following

primary objectives could be defined:

o the compilation of a chronology of historical natural hazard

events in an administrative unit,

o the detailed reconstruction of one single event.

Depending on the defined objectives of the study, different sources or

archives are to be considered. Pointing out the objectives explicitly

facilitates the evaluation of the results and the comparison with other

studies.

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Historical sources and archives

In addition to geophysical instrumentation and dating methods, historical

sources can be utilized for the reconstruction and documentation of

historical events. Sources are defined generally as legacies and written

heritages of former generations. In presence, these sources can be

consulted and interrogated from the point of view of a specific interest.

The information in historical sources has to be made accessible and

appraised throughout a critical review, because the inten-tion of the

source usually had not be focused exclusively on the systematic

documentation of natural hazard events for future generations.

Generally, historical sources can be differentiated between contemporal

and non-contemporal sources. In addition to this differentiation, historical

sources can be divided into printed material, handwritten material,

inscriptions and markers, maps, graphical material and verbal

transmissions (Deutsch & Pörtge 2001).

source type description

printed material chronicles

country reports

pamphlets

travel reports

newspapers

periodicals

annals

etc.

handwritten material chronicles

diaries and journals

visitation reports

tax reports

reports of damages

administration acts

tribunal acts

accounting acts

meeting and inspection protocols

gauge reports and measuring journals

hydraulic engineering and planning reports

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letters and personal documents

religious notes

torrent- and avalanche cadastre

etc.

inscriptions and markers inscriptions

water level markers

floor heightening of buildings

house entrances under basement level

etc.

maps and construction drawings inundation maps

embankment maps

river maps

cadastral maps

construction drawings

etc.

graphical material village sights

copper engravings

river sights

paintings

drawings

photographs

etc.

verbal transmissions testimonies reports

legends

myth’s

sagas

etc.

Table2: Types of sources (after Deutsch & Pörtge 2001, extended on the basis of the

studies elaborated within the framework of Dis-Alp).

The studies elaborated within the framework of Dis-Alp pointed out the

following archives as useful for the research for historical sources:

o archives of the regional authorities with competencies for natural

hazard and disaster management

o archives with technical reports of projects for planning of

mitigation measures

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o regional libraries and archives

o national libraries and national archives

o national databases

o archives of local authorities (cities and communities)

o archives of rectorates

o archives of civil protection organisations (fire brigades, polices,

civil protection authorities)

o private archives

The search for historical documents is to be made in different archives

depending on the objectives of the study. The studies elaborated within

the framework of Dis-Alp pointed out extreme differences in the

existence of historical sources in the archives of the municipalities. In

some archives could be found very valuable documents, whereas in other

archives could be found nothing relevant for the documentation of

natural hazard events. Thus, in this report no generally valid procedure

for the research could be pointed out. In general, only in archives of

important administration authorities (national, regional or city level)

historical sources are archived systematically. The search for historical

sources in the unsystematic administrated archives of small municipalities

is very time-consuming, but often indispensable for the compilation of

the desired information. Historians and historical educated experts whose

are familiar with the regional particularities are indispensable for the

research and evaluation of historical documents. They can abridge the

time needed for the localisation of historical sources and can avoid

misinterpretation. Furthermore, the transcription of historical documents

by historians is an essential precondition for the access to the content of

older documents.

Interpretation of historical sources and extraction of the relevant

information

In addition to the research for historical documents, the viewing, sorting

and evaluating the sources is time-consuming too. The meaningfulness of

historical documents must be assessed by evaluating the framework of

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content and the transmission conditions of the media itself. By evaluating

the framework of content, the origin of the source must be clarified

asking for the locality, the time period, the author and the version. This

information is indispensable for the interpretation of the source within

the historical context. The transmission conditions and the authenticity of

the source can be evaluated by asking for the intention of the document

and by comparing the content with other sources. Contemporal sources

are to prefer to non contemporal sources and duplications. Contemporal

sources contain fewer errors because of the originality of the content.

Compilations of different sources like chronologies often had been

assembled by combining different sources, reliable and unreliable ones.

Thus, the reliability of source compilations is more difficult to evaluate

than of monographs. This type of sources except those ones compiled by

historians must be evaluated by means of a comparison with other

documents with analogical content. The most reliable information about

historical events can be found in official documents from offices for water

resources management or from municipalities written by professionals in

their fields. This type of documents contains information about the

meteorological background and a detailed description of the observed

damages, whereas detailed description of the event itself and his

chronology is missing. Documents from private persons sometimes

contain very valuable information about the chronological process of an

event. Like declarations from testimonials, this information has to be

scrutinized with caution. In addition to the consideration of the intention

and the context of the document, regional and linguistic particularities

have to be concerned. For example the term “high water” often is used

for a high water level in the river channel or for a flood event too.

Attention has to be given to former specifications for measuring

dimensions. The research for and the evaluation of historical documents

preferably has to be undertaken by historians or historical educated

experts who are familiar with the regional particularities. The systematic

compilation and analysis of the information gained by historians should

be made by specialists for natural hazard assessment or engineers. The

extraction of the information about natural hazard events from historical

sources is restricted regarding the completeness of the content. After

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Glaser (2001), from historical documents it is not possible extracting the

information desired from the today’s point of view, but it is possible

extracting only the reliable information of the document considered. The

amount of extractable information is depending on the structure and the

intention of the source. The consideration of local particularities led to a

better understanding and evaluation of the historical sources. A

prerequisite for the systematic documentation of historical events, as

valid for event documentation in general, is that only facts and no

interpretations have to be stored in the appropriate databases. Although

in practice, interpretation in event documentation is not totally excludable

because of the nature of geomorphologic events. In general, the

following information can be gathered from historical sources and

documents:

o information about the type of event (type of process,

answer to the question WHAT)

o information about the date (answer to the question

WHEN)

o information about the process area (answer to the

question WHERE)

o information about the course and the chronology of the event,

about the consequences and damages, about the risk

management (answer to the question HOW)

o information about the weather conditions before and during the

event and about causes and triggering processes (answer to the

questions WHY)

o information about the observer (answer to the question WHO)

For the compilation of a historical natural hazard event in the regional

event database, the minimal information about the process type, the

date and the locality of an event is required. This information fulfils the

general prerequisites for event documentation. The gathered information

about historical natural hazard events usually is archived and stored

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systematically in the appropriate database for event documentation or

media documentation of the regional administration authorities. The

original source must be cited in the event information. The access to the

original sources has to be guarantied for further use in hazard

assessment. Here, for the valid standards for event documentation is

referred to the specific regional regulations and standards. Minimal

requirements are defined by the results of the DOMODIS and Dis-Alp

projects. In the Dis-Alp project, technical standards and data models for

the compilation of historical events in databases have been worked out.

Historical events seldom could be localized and delimitated exactly. Non

two-dimensional de-limitable events have to be localized spatially by

means of points (pair of geographical coordinates). For the localization of

natural processes with an uncertain spatial extent there exist two

approaches: Firstly, an event can be localized through the supposed

centre of the process area or the supposed centre of the administrative

unit, where most of the damages occurred. Secondly, an event can be

localized through the supposed triggering point or the highest point of

the sup-posed triggering area. The choice for the localization approach

depends on the systematic and regulations of the regional event

documentation. In the case of historical events, the first approach is to

prefer because of the lack of information about the triggering areas.

Description of the results

The main results of the research for historical natural hazard events

consist in the compilation of the event documentation databases of the

regional administration authority. After the insertion of the documented

events, the compiled chronology of events and the used sources into the

database, the results of the study can be printed systematically by using

pre-formatted reports. Thus, the final report could be relatively short but

contains the following minimal chapters:

o objectives of the study,

o documentation of the method,

o synthesis of the results,

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o main conclusions.

Opportunities and limitations for the documentation of historical natural hazard events

The compilation of event chronologies enables the analysis of former

dangerous processes. Whit it, dangerous processes and the areas

affected by dangerous processes can be identified and localized. The

characteristics of former processes can be described and the

reoccurrence period can be estimated. Thus, the systematic

documentation of historical natural hazard events contributes to the

assessment of recent and potential future processes. Furthermore,

objective information about former processes can be used in risk

communication. Although these opportunities, during the interpretation

of this information the following particulars have to be kept in mind:

o The documentation of historical events contains only qualitative

descriptions.

o In past times, only events with a certain process magnitude or

events with relevant damages had been described and

documented.

o Changes within the system man-environment since the

documented historical event have to be considered. For example,

some flood events as described in historical documents can not

occur today because of anthropogenic or natural modifications of

the river channel like channel straightening and silting up or

erosion of the river bed. Sys-tem changes due to climate

changes since the “little ice age” have to be considered, too.

o Temporal and spatial shifts or changes of the damage potential

since the documented historical events have to be considered in

risk analysis.

The studies elaborated within the framework of Dis-Alp synthetically

pointed out the following opportunities and limitations for the

documentation of historical natural hazard events:

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objective opportunities limitations

compilation of a chronology of

natural hazard events in an

administrative unit

identification and localization of

endangered areas

identification of endangered objects

help for the estimation of the

reoccurrence interval

risk communication

information of the public

only qualitative process description

available

few information about the magnitude

of processes available

no documentation of processes with

low magnitudes or without related

damages available

no transferability of particulars of one

event to others in neighboured

regions possible

no exact spatial delimitation of events

possible

reconstruction of one single

historical natural hazard event

information about the temporal

development of one single event

information about the process

characteristics

spatial delimitation about the run out

areas

assessment of the amount of and the

spatial allocation of damages

assessment of potential future

consequences

derivation of spatial characteristics or

environmental parameters for

subsequent process simulations

verification of simulation results

assessment of the magnitude and

intensity of dangerous processes

foundation of the hazard assessment

information of the public

mainly qualitative or semiquantitative

information about historical events

available

few information about the triggering

areas or about the basin of natural

processes available

exact spatial delimitation only

through the interpretation of

photographs possible

Table 3: Opportunities and limitations for the documentation of historical natural hazard

events.

Although these and further limitations for the interpretation and analysis

of historical events, the acquired information can enhance the existing

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fundamental data needed for natural hazard assessment in a valuable

dimension. Due to the mainly qualitative information about the undesired

consequences of dangerous processes, this kind of information can be

understood easily and unambiguously by the public. Thus, beside the

applications in technical risk management, the analysis of historical

natural hazard events can be particularly helpful in risk communication.

Experiences of historical natural hazard events documentation

(Institute of Mountain Risk Engineering – IAN, BOKU)

Besides the above mentioned participants, the Institute of Mountain Risk

Engineering at the University of Natural Resources and Applied Life

Science in Vienna (BOKU) also conducted a compilation of natural hazard

events information. The academic library of the institute owns a

handwritten chronicle, dealing with floods and torrential devastations,

landslides, debris flows and rockfalls in Tyrol and Vorarlberg up to 1891.

Referring to Stiny (1938), the author of this chronicle is Dr. Georg Strele,

a former head of the Austrian Service for Torrent and Avalanche Control

in Tyrol. The chronicle was transcribed on the one hand by the

department 30 of the Autonomous Province of Bolzano, South Tyrol and

on the other hand by Josef Plank in conjunction with his unpublished

master thesis in 1995. To have two transcribed versions of this chronicle

was helpful, as a comparison of these two made it possible to find out

transcription errors.

To split the chronicle into individual and meaningful datasets was the

most time-consuming part of this work. These datasets should follow the

DIS-ALP standard and give at least an answer to the three main

questions (what, when, where). The main focus of this work was the

spatial mapping of the damages and the identification of the causing

water bodies. The first mentioned event took place in the 4th century.

The time and location information of this time period is pretty inaccurate,

but it is getting more precise for younger events.

A few of the above mentioned issues became also relevant in this work:

o In general, the compilation of historical hazard events is very

time-consuming.

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o The transcription of historical documents is essential. In this

case, the chronicle was written in Korenth script (old German

script) which increased the possibility of transcription errors.

o At least the author, the locality and the date of the chronicle

should be known.

o The sometimes more general description of events made it

difficult to extract reliable and precise information

It was attempted to avoid any kind of interpretation, but linguistic

particularities made it sometimes necessary. The author of the chronicle

used terms which are not part of the DIS-ALP standard any more to

describe the events. These terms had to be converted. Hence, a

framework was set up to harmonise the conversion within all datasets.

Spatial Planning and Risk management requirements

In this report the description of data requirements is restricted to those

data, which can and should be provided by the experts dealing with

natural hazards. There may be some more information or preparation

needed, e.g. for the organization of risk management, but this has to be

done in an other context e.g. platform natural disasters by the Swiss

example.

Requirements of spatial planning and risk management are to a great

extent the same (also for house - owners etc.):

Requirements for spatial planning

o Type of process(es) to be expected (e.g. flood, debris flow,

landslide,, soil erosion, avalanches, rockfall, etc.)

o Reoccurrence period (every 30 and 100 years) in particular for

floods and avalanches. Difficult or even impossible for e.g. mass

movements.

o Affected area and according Intensity, impact in a general scale

(very high , high, medium, low, very low ).

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o Detailed information (e.g. depth, height, width) related to the

specific process.

o Level of protection works, residual risk.

o Endangered area in case of failure of protection works (this

information must be coloured separately).

o Possibilities / necessities for private precaution, prevention:

differentiated due to the process: in form of remarks for the

particular area.

o Appropriate use possible or maybe better the contrary case: not

possible kinds of land use (general standards)

The appropriate land use as mentioned in point 8 must be the result of

an open discussion in the public / community and regulated in general

standards. This is not the duty of the expert.

Requirements for risk management

As discussed at the 1st workshop in Salzburg the term "risk engineering"

should be substituted by "risk management".

More or less the data as mentioned above are also needed for risk

management. Based on this information the according organization may

consider topics like:

o Type of process(es) to be expected

o Affected area, number of people

o Velocity of process; early warning system possible ? Time for

warning / evacuation ? How much time ?

o Safe access and rescue ares

o Critical spots, equipment needed

Requirements for the experts

The information mentioned above have to be supplied by skilled experts.

To be able to do so the experts need in addition more detailed

information depending on the type of process:

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o Reliable, sound documentation of disasters such as:

• Performance of process (start, peak, end)

• Triggering factors, climatic situation, precipitation

• Intensity, impact in terms of forces, pressures ( e.g.

pressures in case of avalanches).

o Magnitude and frequency (discharge, volume, masses etc.; re-

occurrence period)

o Information about silent witnesses and documents of historical

processes: Location, affected area, .reports, photographs and

other documents in an event-register.

o Basic information such as e.g. geological maps, geomorphologic

maps etc.

In addition a number of more data will be needed for a full

understanding and assessment of an event, e.g. landslides, debris flow

etc. In the context of this report it seems not to be helpful to list all these

data here; this has to be decided by an expert related to the specific local

situation.

DIS-ALP web portal

The intention of the DIS-ALP Web - Portal is to provide an exchange

platform for experts, planning institutions and the interested public on

disaster events in alpine regions and on related background information

(“knowledge”). Consequently data for each event recorded are presented

in the degree of detail corresponding to the requirements, defined in

DIS-ALP methodology.

This means the maximum information detail of the DIS-ALP web portal is

defined by the DIS-ALP 5 W standard (which, when, where, why, who).

For historical event data the 3 W standard is used (which, where, when).

It is not intention of DIS-ALP portal to duplicate the entire volume of

detailed information collected by the responsible organizations, but rather

to offer a possibility to integrate event data throughout the alps from a

wide variety of organisations.

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For this end the following design principles were used in the development

of the DIS-ALP portal, which is available at portal.dis-alp.org:

o open interfaces, with the use of standards such as the OGIS

standards GML and WFS for data integration, WMS for web

mapping, OWL for knowledge representation and SOAP services

for communication purposes;

o integration of existing platforms via the defined open interfaces

in order to avoid data redundancy (e.g. WLV event portal in

Austria, Salzburg historical events, Bavaria archives, STORME...);

o multilingual user interface, including database content;

o a knowledge base, as solution for formally structuring the

knowledge background necessary for using event data and for

future planning and disaster mitigation measures;

o easy-to-use interface for wide access to data and background

information.

Figure 24: DIS-ALP Web Portal: Basic event overview

In general the portal is separated into two main activity fields. A

navigation-tree on the left side provides all the functionality dealing with

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event data and knowledge. In more detail 3 fundamental function groups

are available:

o "Upload", gives the user the possibility to load events after a pre-

defined standard to the DIS-ALP Portal. See also chapter “Data

Upload”.

o "Events", this function offers the possibility to view and filter

desired event information. Events are presented as points at the

Web GIS surface of the Portal. Associated attributes can easily be

queried in detail.

o "Knowledge", gives information to the user about general

background knowledge from the ontology based DIS-ALP

knowledge base.

On the right side, the user can choose between a cartographical

presentation to get information about event data and a specific detailed

knowledge presentation.

The event data is represented as point information on the map, which is

corresponding to the information detail represented within DIS-ALP. The

data itself can be directly stored in the DIS-ALP (PostGIS) database,

when uploaded by a user. Alternativly (and preferrably) a co-operating

institutions links its own event data via a DIS-ALP conforming WFS.

Functions for map interaction are available in the map representation,

like pan, zoom, individually choosen legends or information requests

(Figure 25). This functionality is extendable to meet future requirements.

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Figure 25: DIS-ALP Portal – detailed information view of events

Background knowledge is provided through the [List] register-card.

Definitions, photos and hierarchical structure of the questioned term are

displayed.

Figure 26: DIS-ALP Portal – view with knowledge query

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Data integration into DIS-ALP portal

There are two different possibilities of integrating event data within

DIS-ALP:

o Bulk Insert via data upload,

o Web Feature Service (WFS), corresponding to DIS-ALP

specifications.

Bulk Insert of individual data

This data upload possibility is based on a XML transformation of an

individually database which is then be directly imported into the DIS-ALP

database via the DIS-ALP Portal.

There are five working steps required to use the Bulk Insert functionality

of the DIS-ALP Portal, see Figure below.

Figure 27: XML transformation of your database and import via DIS-ALP portal (Bulk

Insert).

o Database Mapping converts individual tables to DIS-ALP-

structure.

o Generate XML means to transform the related data into XML

(Extended Markup Language) format.

o XSLT (XML Transformation) is used to transform XML-documents

into valid Geographical Markup Language (GML) files.

XSLTGenerate XML

OGC WCTS

Insert WFSDatabase Mapping

XSLTGenerate XML

OGC WCTS

Insert WFSDatabase Mapping

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o OGC WCTS „Web Coordinate Transformation Service“. This is a

“defacto”-standard, defined by OGC for coordinate

transformation between different coordinate systems.

o Carry out data-upload via DIS-ALP Portal, figure below.

Figure 28: Web upload front end DIS-ALP Portal

Setup of a DIS-ALP conforming Web Feature Service (WFS).

The idea behind the second integration possibility is to extend individually

databases by Web Feature Service implementation. Data of Partner-WFS

are integrated within DIS-ALP as WFS and represented to the end-user

via cascading WFS as Mapping Service (WMS). This solutions provides

several advantages:

o manage data in a future oriented way:

o exchange data with DIS-ALP WFS with a minimum effort;

o no duplication of data;

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• no download of full datasets possible by end-users (end-

user only has WMS available).

For detailed information about basic requirements, security

considerations as well as final implementation see Annex

(Implementation of dedicated WFS).

Event Functionality

The portal provides the possibility to query and display event information.

Controlled by the navigation-tree at the left side of the portal the

following event driven activities can be triggered:

o Load events

Select the organisations which provide event information.

o Filter events

This function represents the event query management. With the

providing filter form (Figure 29) it’s possible to search for event

information by selecting thematic, spatial and temporal context.

Figure 29: Query filter – DIS-ALP Portal

o Export events

Authorised users can export requested event information.

o Event statistics

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Predefined statistical queries can be selected. This activity makes

sense for often used queries.

DIS-ALP Web Services

The DIS ALP portal is to be regarded both as a producer and consumer

of Web Services.

As a producer DIS ALP offers a WMS for event maps (defined as OGC

conformal WMS), a data service for online-queries from event data as

well as a knowledge service for the technical access to the DIS ALP

knowledge database. Since for thematically oriented data services and

knowledge services (contrary to WMS) no internationally recognized

standards can be resorted to, these services (DIXIE for data service and

OWL for knowledge service) are defined and made available over SOAP.

Three services are implemented within DIS-ALP:

Knowledge Service Functions for the use of the knowledge

data base in service form.

Data Service Supply and upload of structured event

data.

Map Service Functions for the use of event maps in

service form.

Map services are well covered by the use of WMS, both for integrating

external mapping ressources and for providing maps in service form. In

DIS-ALP WMS is used for both purposes.

Data exchange services are used only at the input side, DIXIE XML for

upload purposes and a simplified GML version as basis for WFS

integration.

DIS-ALP knowledge service internally uses OWL and provides special

functions for knowledge queries (e.g. getDefinition, getTranslation,

getFullObject), which are returned as XML representation of object

structure. This functionality is directly accessed by the navigation tree

component and the knowledge view.

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References

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Die Sprache der "Stummen Zeugen". Interpraevent,

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BARNIKEL, F. (2004):

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BECHT, M., COPIEN, C., and FRANK, C. (2005):

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BECHT, M., COPIEN, C., and FRANK, C. (2005):

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CAILLEUX, A. & TRICART, L. (1959):

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D'Agostino, V. and Vesca, M. (2005):

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Tinne.

DEUTSCH, M. and PÖRTGE, K., (2001):

Historische Hochwasserinformationen - Möglichkeiten und

Grenzen ihrer anwendungsbezogenen Auswertung. In: ATV-

DVWK Landesverband Bayern (ed.), Hochwasser - Niedrigwasser

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GLASER, R. (2001):

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SCHEIDL C., KOLLARITS S., HOCEVAR A. (2005):

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Brixner Talbecken. Erfassung bestehender Unterlagen und

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ZISCHG, A. (2005):

Rekonstruktion historischer Überschwemmungsereignisse im

Sterzinger Talbecken. Erfassung bestehender Unterlagen und

Eingabe in ED30. Dis-Alp Projektbericht für die Autonome Provinz

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Project Consortium

BMLFUW/Forestry Austria

Austrian Federal Ministry of Agriculture, Forestry,

the Environment and Water Resources;

Department 4: Forestry Section

BMLFUW/Water Austria

Austrian Federal Ministry of Agriculture, Forestry,

the Environment and Water Resources;

Department 5: Water Section

SALZBURG Austria

Land Salzburg;

Department 7: Spatial Planning

BAVARIA Germany

Bavarian Ministry of Regional Development and

the Environment;

Department 5: Water Management

BOZEN Italy

Autonome Provinz Bozen;

Sonderbetrieb für Bodenschutz, Wildbach- und

Lawinenverbauung

TRENTO Italy

Provincia Autonoma di Trento;

Servizio di Sistemazione Montana

SLOVENIA Slovenia

Torrent and Erosion Control Service Slovenia

SCHWEIZ Schweiz

Bundesamt für Umwelt, Wald und Landschaft

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Participants

Hubert Siegel; Dipl.-Ing. Lead Partner

BMLFUW Sektion IV (Forstwesen) Abteilung 4b

Marxergasse 2 A-1030-Wien Tel.: 0043/1/711 00-7204 hubert.siegel@lebensministerium.at

Gerhard Mannsberger; Dipl.-Ing. Lead Partner

BMLFUW Sektion IV (Forstwesen) Marxergasse 2 A-1030-Wien Tel.: 0043/1/711 00-730 gerhard.mannsberger@lebensministerium.at

Ingo Schnetzer; Dipl.-Ing. Technical Project Coordination

WLV Stabstelle Geoinformation Stubenring 1 A-1012 Wien Tel.: 0043/1/71100-2350 Fax: 0043/1/71100-2359 ingo.schnetzer@die-wildbach.at

Stefan Kollarits; Mag. Dr. Project Management

PRISMA solutions Klostergasse 18 A-2340 - Mödling Tel.: 0043/2236/47975-13 Mob: 0043/664/4509206 stefan.kollarits@prisma-solutions.at

Christian Scheidl; Dipl.-Ing. Project Management

PRISMA solutions Klostergasse 18 A-2340 Mödling Tel.:0043/2236/47975-21 christian.scheidl@prisma-solutions.at

Klaus-Peter Hanten; Dipl.-Ing. Project Partner: 1

Bundesministerium für Land- und Forstwirtschaft, Umwelt und Wasserwirtschaft

Marxergasse 2 A-1030-Wien Tel.: 0043/1/71100/7136 klaus-peter.hanten@lebensministerium.at

Drago Pleschko; Dipl.-Ing. Project Partner: 1

Bundesministerium für Land- und Forstwirtschaft, Umwelt und Wasserwirtschaft

Marxergasse 2 A-1030-Wien Tel.: 0043/1/71100/7135 drago.pleschko@lebensministerium.at

Wolfgang Haussteiner; Dipl.-Ing. Abteilungsleiter Project Partner: 1

Amt der Salzburger Landesregierung Fachabteilung 6/6: Wasserwirtschaf

Postfach 527 A-5010 Salzburg Tel.: 0043/662 8042 /4539 Fax: 0043/662 8042 /4199 wolfgang.haussteiner@salzburg.gv.at

Robert Loizl; Dipl.-Ing. Project Partner: 1

Amt der Salzburger Landesregierung Fachabteilung 6/6: Wasserwirtschaf

Postfach 527 A-5010 Salzburg Tel.: 0043/662 8042 /4263 Fax: 0043/662 8042 /4199 robert.loizl@salzburg.gv.at

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Friedrich Mair; Ing. Dr. Abteilungsleiter Project Partner: 2

Amt der Salzburger Landesregierung Abteilung 7: Raumplanung

Michael-Pacher-Straße 36 A-5020 Salzburg Tel.: 0043/662/8042-4387 friedrich.mair@salzburg.gv.at

Franz Dollinger; Dr. Referatsleiter Project Partner: 2

Amt der Salzburger Landesregierung Abteilung 7: Raumplanung Fachref. 7/02: Raumforschung und grenzüberschreitende Raumplanung

Michael-Pacher-Straße 36 A-5020 Salzburg Tel.: 0043/662/804 2-4650 franz.dollinger@salzburg.gv.at

Andreas Holderer; Dipl.-Ing. Project Partner: 3

Bayrisches Umweltministerium Rosenkavalierplatz 2 D-81925 München Tel.: 0049/89/921/443/16 andreas.holderer@stmlu.bayern.de

Anton Loipersberger; Dipl.-Ing. Project Partner: 3

Bayer. Landesamt für Umwelt Dienstort München Referat 61 - Hochwasserschutz und alpine Naturgefahren

Bayer. Landesamt für Umwelt Dienstort München Postfach 19 02 41 D-80 602 München Tel.: 0049/89/9214/1042 Fax: 0049/89/9214/1041 anton.loipersberger@lfw.bayern.de

Rudolf Pollinger Dr. Project Partner: 4

Autonome Provinz Bozen Sonderbetrieb für Bodenschutz, Wildbach- und Lawinenverbauung

Caesare-Battisti-Str. 23 I-39100 Bozen Tel.: 0039/0471/414/550 Fax: 0039/0471/414/599 rudolf.pollinger@provinz.bz.it

Hans-Peter Staffler Dr. Project Partner: 4

Autonome Provinz Bozen Sonderbetrieb für Bodenschutz, Wildbach- und Lawinenverbauung

Caesare-Battisti-Str. 23 I-39100 Bozen Tel.: 0039/0471/414/ Fax: 0039/0471/414/599 hanspeter.staffler@provinz.bz.it

Bruno Mazzorana; Dr. Project Partner: 4

Autonome Provinz Bozen Sonderbetrieb für Bodenschutz, Wildbach- und Lawinenverbauung

Caesare-Battisti-Str. 23 I-39100 Bozen Tel.: 0039/0471/414/567 Fax: 0039/0471/414/599 bruno.mazzorana@provinz.bz.it

Elisabeth Berger; Dr. Project Partner: 4

Autonome Provinz Bozen Sonderbetrieb für Bodenschutz, Wildbach- und Lawinenverbauung

Caesare-Battisti-Str. 23 I-39100 Bozen Tel.: 0039/0471/414/569 Fax: 0039/0471/414/599 elisabeth.berger@provinz.bz.it

Pierpaolo Macconi; Dr. Project Partner: 4

Autonome Provinz Bozen Sonderbetrieb für Bodenschutz, Wildbach- und Lawinenverbauung

Caesare-Battisti-Str. 23 I-39100 Bozen Tel.: 0039/0471/414 588 pierpaolo.macconi@provinz.bz.it

Mario Cerato; Dr. Project Partner: 5

c/o Servizio Sistemazione Montana Via G.B. Trener, 3 I-38100 Trento Tel.: 0039/0461/495703 mario.cerato@provincia.tn.it

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Aldo Caserotti; Dr. Project Partner: 5

c/o Servizio Sistemazione Montana Via G.B. Trener, 3 I-38100 Trento Tel.: 0039/0461/495695 aldo.caserotti@provincia.tn.it

Silvio Grisotto; Dr. Project Partner: 5

c/o Servizio Sistemazione Montana Via G.B. Trener, 3 I-38100 Trento Tel.: 0039/349/788/6772 dis-alp.trento@provincia.tn.it

Aleš Horvat Prof. Dr. Project Partner: 6

Torrent and Erosion Control Service – Slowenien PUH d.d.

Tel.: +386/1/4775200 ales.horvat@puh.si

Jože Papež Dipl.Ing. Project Partner: 6

Torrent and Erosion Control Service – Slowenien PUH d.d.

Tel.: +386/1/4775200 joze.papez@puh.si

Werner Schärer Dipl. Forsting. ETH, lic. Iur. Forstdirektor Project Partner: 7

Bundesamt für Umwelt, Wald und Landschaft (BUWAL) Forstdirektion

Papiermühlestrasse 172 Ittigen CH-3003 Bern Tel.: 0041/31/324/7836 Fax: 0041/31/324/7866 werner.schaerer@buwal.admin.ch

Marzio Giamboni; Dr. Project Partner: 7

Bundesamt für Umwelt, Wald und Landschaft

Papiermühlestrasse 172 Ittigen CH-3003 Bern Tel.: 0041/31/324/8640 Fax: 0041/31/324/7866 marzio.giamboni@buwal.admin.ch www.schutzwald-schweiz.ch

Franziska Schmid Dipl. Geogr. Project Partner: 7

Geographisches Institut der Universität Bern

Geographisches Institut der Universität Bern CH-3012 Bern Tel.: 0041/31/6318390 Fax.: 0041/31/6318511 fschmid@giub.unibe.ch

Simon Burren; Dr. Project Partner: 7

Bundesamt für Umwelt, Wald und Landschaft

Papiermühlestrasse 172 Ittigen CH-3003 Bern www.schutzwald-schweiz.ch

Walter Riedler Mag. Consultant

Salzburger Institut für Raumordnung und Wohnen

Alpenstr. 47 A-5020 Salzburg Tel.: 0043/662/623455/18 walter.riedler@salzburg.gv.at

Lorenzo Marchi; Dr. Consultant

CNR IRPI - Padova Corso Stati Uniti 4 35127 Padova Italy lorenzo.marchi@irpi.cnr.it

Sebastiano Trevisani; Dr. Consultant

CNR IRPI - Padova Tel.: 0039/0347/1189687 sebastiano.trevisani@unip.it

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Marco Cavalli; Dr. Consultant

CNR IRPI - Padova Corso Stati Uniti 4 35127 Padova Italy marco.cavalli@irpi.cnr.it

Hannes Hübl; Prof. Dr. Consultant

Universität für Bodenkultur Wien Institut für Alpine Naturgefahren Department für Bautechnik und Naturgefahren

Peter-Jordan Strasse 82 A-1190 Wien Tel.: direct: 0043/1/47654/4352 Tel.: office: 0043/1/47654/4350 Mob.: 0043/664/5110495 Fax: 0043/1/47654/4390 johannes.huebl@boku.ac.at

Egon Ganahl; Dipl. – Ing. Consultant

Universität für Bodenkultur Wien Institut für Alpine Naturgefahren Department für Bautechnik und Naturgefahren

Peter-Jordan Strasse 82 A-1190 Wien

Peter Agner; Dipl. – Ing. Consultant

Universität für Bodenkultur Wien Institut für Alpine Naturgefahren Department für Bautechnik und Naturgefahren

Peter-Jordan Strasse 82 A-1190 Wien

Markus Moser; Dipl. – Ing. Consultant

Universität für Bodenkultur Wien Institut für Alpine Naturgefahren Department für Bautechnik und Naturgefahren

Peter-Jordan Strasse 82 A-1190 Wien

Willibald Kerschbaumsteiner; Dipl. – Ing. Consultant

Universität für Bodenkultur Wien Institut für Wasserwirtschaft, Hydrologie und konstruktiven Wasserbau

Muthgasse 18 A-1190 Wien Tel: 0043/1/36006-5525 Fax: 0043/1/36006-5549 willibald.kerschbaumsteiner@boku.ac.at

Hans Kienholz; Prof. Dr. Consultant

University of Bern Geographical Institute Applied Geomorphology & Natural Risks

Hallerstrasse 12 CH-3012 Berne Tel.: 0041/31/631/8884 or: 0041/31/372/9031 or: 0041/31/631/8859 secr. Fax: 0041/31/631/8511 kienholz@giub.unibe.ch

Diethard Leber; Univ.-Lektor Mag. Dr. Consultant Remote Sensing

GeoExpert Research & Planning GmbH

Brunhildengasse 1/1, A-1150 Wien Tel.: 0043/1/36744 05 50 Fax: 0043/1/3674405 55 Diethard.Leber@geoexpert.at

Tanja Nössing; Mag.rer.nat. Consultant

G. di Vittorio Str. 29/c I-39100 Bozen Tel.: 0093/0349/4443931 tanja.noessing@rolmail.net

Michael Becht; Prof. Dr. Consultant

Katholische Universität Eichstätt-Ingolstadt Lehrstuhl für physische Geographie

Ostenstrasse 18 85072 Eichstätt Tel.: 0049/8421 93 – 1303 Fax: 0049/8421 93 – 2302 michael.becht@ku-eichstaett.de

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Detailed annexes

The detailed reports in the original languages can be found on the

DIS-ALP website (http://www.dis-

alp.org/index.php?module=ContentExpress&func=display&ceid=118) or

linked below:

Methodology (WP5)

o Methodology-Band1.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP5/

Methodology-Band1.pdf)

o Methodology-Band2.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP5/

Methodology-Band2.pdf)

o Methodology-Band1-Appendix1.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP5/

Methodology-Band1-Appendix1.pdf)

o Methodology-Band1-Appendix2.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP5/

Methodology-Band1-Appendix2.pdf)

o Methodology-Band1-Appendix3.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP5/

Methodology-Band1-Appendix3.pdf)

System development (WP6)

o Setup_of_WFS

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP6/

DIS_ALP_WFS_setup.pdf)

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New Tools (WP7)

o WP7_1.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP7/

WP7_1.pdf)

o WP7_2.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP7/

WP7_2.pdf)

o DISALP_Fernerkundung_LEBER.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP7/

DISALP_Fernerkundung_LEBER.pdf)

o GeoExpert_Teil_B_Felddatenerhebung.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP7/

GeoExpert_Teil_B_Felddatenerhebung.pdf)

Instruction

o DISALP-Feldanleitung_germ.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP8/

DISALP-Feldanleitung_germ.pdf)

o KurzberichtSchulen_engl.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP8/

KurzberichtSchulen_engl.pdf)

Implementation

o HAWAS_Abschlussbericht-Juli_2005_englisch.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP9/

HAWAS_Abschlussbericht-Juli 2005_englisch.pdf)

96 / 96

DIS-ALP

FINAL REPORT

o Disalp_Tinne_Nov.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP9/

Disalp_Tinne_Nov.pdf)

o Bericht_Brixen-1.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP9/

Bericht_Brixen-1.pdf)

o Disalp_HistorischeEreignisse-2.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP9/

Disalp_HistorischeEreignisse-2.pdf)

o IAN-Historische_Ereignisse.pdf

(http://www.dis-

alp.org/modules/UpDownload/store_folder/Work_Packages/WP9/

IAN-Historische Ereignisse.pdf)