Difference between revisions of "DTRAN"

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• Developed by [[Emin Zeki BAŞKENT]], [[Sedat KELEŞ]] and [[Ali İhsan KADIOĞULLARI]]  
 
• Developed by [[Emin Zeki BAŞKENT]], [[Sedat KELEŞ]] and [[Ali İhsan KADIOĞULLARI]]  
 
• [[ETÇAP]] is in this moment ready to be used in some forest management planning units  (Kızılcasu-Cide; Gürgendağ-Edremit; Honaz-Denizli and Akseki-İbradı) in Turkey and will be soon adapted to other Turkish regions after evaluation by the Forest Management Department in Turkish Forest Service
 
• [[ETÇAP]] is in this moment ready to be used in some forest management planning units  (Kızılcasu-Cide; Gürgendağ-Edremit; Honaz-Denizli and Akseki-İbradı) in Turkey and will be soon adapted to other Turkish regions after evaluation by the Forest Management Department in Turkish Forest Service
[[Category:Turkish DSS]]
+
[[Category: Turkish DSS]]
 
[[Category: Traditional simulation]]
 
[[Category: Traditional simulation]]
 
[[Category: Simulated annealing]]
 
[[Category: Simulated annealing]]
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[[Category: Linear programming]]
 
[[Category: Linear programming]]
 
[[Category: Decision support system]]
 
[[Category: Decision support system]]
 +
[[Category: Strategic plannig]]
 +
[[Category: harvest scheduling]]
 +
[[Category: spatial planning]]
 +
  
 
=== Support for specific issues  ===
 
=== Support for specific issues  ===
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=== Support for specific thematic areas of a problem type  ===
 
=== Support for specific thematic areas of a problem type  ===
Timber cruising
+
* Timber cruising
Silvicultural  
+
* Silvicultural  
Certification  
+
* Certification  
Conservation  
+
* Conservation  
Development choices / land use zoning  
+
* Development choices / land use zoning  
Policy/intervention alternatives  
+
* Policy/intervention alternatives  
Spatial layout of interventions
+
* Spatial layout of interventions
  
 
=== Capability to support decision making phases  ===  
 
=== Capability to support decision making phases  ===  
Line 47: Line 51:
  
 
=== Related systems  ===
 
=== Related systems  ===
Describe (and/or link to) other systems related
+
* [[AROBEM]] (empirical growth and yield model inherent in ETÇAP)
 +
* [[ETÇAPKlasik]]
 +
* [[ETÇAPSimulation]]
 +
* [[ETÇAPOptimization]]
 +
* [[ETÇAPKombineOptimization]]
  
 
== Data and data models ==
 
== Data and data models ==
  
 
=== Typical spatial extent of application  ===
 
=== Typical spatial extent of application  ===
Define the scale of use for the application (user defined, regional, multi-owner forest single ownership forest, Multiple scale interaction)
+
The normal spatial application level of ETÇAP is the forest level with various stands.  Yet the spatial resolution of the model is the stand, the smallest identifiable unit of forest area.
  
 
=== Forest data input  ===
 
=== Forest data input  ===
Describe the basic forest input (forest level, stand level, or individual tree level), and appropriate meta-data, such as data provenance (Areal coverage, Sample of plots, stands, Contiguous forest cover). GIS information is to be considered here, namely include cover tyes and type of information (raster or vectorial, necessity of topological information) If necessary describe surrogate sources of information
+
ETÇAP input information are inventory data that can be imported from files with .xls or .mdb extensions with a specific format.
 +
The input data required depends on the characteristics of the stand. Three groups of data are needed for the model; the current area of the stands generated by a GIS software, current status of each stand measured with inventory sheets for per area growth and yield characteristics (in each plot: the plot size, diameters of all stems, ages of some stems, age and dominant height for a number of stems, and ten-last-years growth for  some trees) and the other support tables (volume table, empirical yield table, site index table, product assortment table and financial value table) characteristics
 +
In order to allow spatial layout of a harvest schedule for visualization and generation of maps, compartments, forest stratifications and analysis areas have to be set and related to each polygon (a sub-compartment =stand) with geographic files
  
 
If necessary describe other types of required data (economic, social)
 
If necessary describe other types of required data (economic, social)
  
 
=== Type of information input from user (via GUI) ===
 
=== Type of information input from user (via GUI) ===
Describe what is the information that the user directly inputs in the system if any): expert knowledge, opinion, goals and production objectives, preferences, stand/site information....
+
Forest management strategies with specific objectives and constraints have to be developed as shown in the user interface. More than one goal may be selected to address multi-objective management of forests. The indicated targets as management objectives are both yield-economic goals and conservation targets.  
  
 
== Models ==
 
== Models ==
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=== Forest models ===
 
=== Forest models ===
 
Models implemented in ETÇAP simulate  silvicultural treatment schedules according to the stand variables previously given based on both optimization and simulation techniques.  
 
Models implemented in ETÇAP simulate  silvicultural treatment schedules according to the stand variables previously given based on both optimization and simulation techniques.  
Currently ETÇAP has implemented models for the management of either even-aged, uneven-aged, pures or mixed forest stands of any species that have the growth and yield data
+
Currently ETÇAP has implemented models for the management of either even-aged, uneven-aged, pures or mixed forest stands of any species that have the growth and yield data  
  
 
=== Social models  ===
 
=== Social models  ===
historical and cultural values of sites, values due to peace and quiet, esthetic values, values due to recreational activities, ethical values): E. g. Recreation, Health, Game
+
-Not available yet
 
+
  
 
== Decision Support ==
 
== Decision Support ==
  
 
=== Definition of management interventions ===
 
=== Definition of management interventions ===
Define what is available for the manager to intervene in the forest: time of harvest, plantations, thinnings, reconversions...
+
The user lays out the alternative management prescriptions as sequences of silvicultural treatments; how, when (time of harvest, regeneration methods, thinnings, etc.) and where (a stand or a contiguous group of stands) the treatments could be conducted in order to achieve the previously chosen management targets.  
Existence of prescription writer, simple enumeration of all possibilities, scenario simulation , etc.  
+
  
 
=== Typical temporal scale of application ===
 
=== Typical temporal scale of application ===
Define the temporal scale of the application: E.g., operational and immediate level, Tactical planning (short term) and strategic level.  
+
Strategic and tactical planning.  
  
 
=== Types of decisions supported  ===
 
=== Types of decisions supported  ===
*Management level  
+
* Management level  
**strategic decisions
+
** Strategic decisions  
**administrative decisions
+
** Operating control decisions  
**operating control decisions
+
* Management function  
* Management function
+
* planning decisions
+
**organizing decisions
+
**command decisions
+
**control decisions
+
** coordination decisions
+
*decision making situation
+
**unilateral
+
** collegial
+
**Bargaining / participative decision making
+
  
 
=== Decision-making processes and models ===
 
=== Decision-making processes and models ===
*Logic modeling
+
* Traditional simulation
*Operations research modeling
+
* Simulated annealing
**Direct approaches
+
* Random ascent
**Heuristic manipulation of simulation models
+
* Linear programming
*Business modeling
+
 
*Simulation (with and without stochasticity)
+
*Multiple criteria/ranking
+
*Other
+
  
 
== Output ==
 
== Output ==
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=== Types of  outputs ===
 
=== Types of  outputs ===
  
Types of outputs produced (tables, maps, 3-D visualizations, pre-programmed summaries, etc)
+
* Stand level table and graphical outputs showing the temporal changes of its parameters
 +
* Forest level outputs showing the performance of forest dynamics based on selected performance indicators in various display formats (bar chart, line chart, table format)
 +
* Forest level map display depicting the long term harvest schedules (regeneration, thinning, and aforestation)
  
 
=== Spatial analysis capabilities  ===
 
=== Spatial analysis capabilities  ===
 
* integrated capabilities  
 
* integrated capabilities  
* facilitates links to GIS (wizards, etc.)
+
* facilitates links to GIS
 
* provides standard data import/export formats  
 
* provides standard data import/export formats  
* allows spatial analysis (e.g. topology overlays (e.g. multi layering of different maps, selection of objects based on selection criteria, aggregation by attributes (e.g. areas of similar characteristics), Linking by logical means, Statistics by area, analysis with digital terrain model)
+
* allows spatial query
 +
* statistics by area
 +
 
  
 
=== Abilities to address interdisciplinary, multi-scaled, and political issues  ===
 
=== Abilities to address interdisciplinary, multi-scaled, and political issues  ===
Evaluate interactions between different basic information types (biophysical, economic, social). Produce coordinated results for decision makers operating at different spatial scales facilitate social negotiation and learning
+
Evaluate interactions between different basic information types (biophysical, economic, social).  
  
 
== System ==
 
== System ==
  
 
=== System requirements  ===
 
=== System requirements  ===
* Operating Systems: (Windows, Macintosh, Linux/UNIX, Web-based, Others)  
+
* Operating Systems: (Windows)  
* Other software needed (GIS, MIP packages, etc...)
+
* Other software needed (GIS, LINDO, Access and other free software development kits)  
* Development status
+
  
 
=== Architecture and major DSS components ===
 
=== Architecture and major DSS components ===
Describe the basic architecture of the system in software and hardware. Desktop client-server, web based, as well as the  integration with available systems. Basic data flow, focusing on retrieval of required input and propagation and implementations of decisions. Mention its modular and scalability capabilities.
+
Desktop client-server system of architecture is in place
  
 
=== Usage ===
 
=== Usage ===
Describe the level of use: Research level use, Industry use, Government use
+
Research level use, government use  
  
 
=== Computational limitations ===
 
=== Computational limitations ===
Describe the system limitations: e.g. number of management units, number of vehicles, time horizon
+
No limitation on the number of stands as long as hardware components (RAM and disk space) are not limiting. Time horizon for optimization is about twice the rotation period.
  
 
=== User interface ===
 
=== User interface ===
Describe the quality of user interface and the Prerequisite knowledge for using the system
+
In-hose developed GUI is available
  
 
=== Documentation and support ===
 
=== Documentation and support ===
Describe the connection to Help-system and possibilities for assistance, as well as the required training and user support levels
+
No manual is ready now
  
 
=== Installation ===
 
=== Installation ===
* Prerequisite knowledge: Level of effort to become functional
+
* Level of effort to become functional  
* Cost: (purchase price, development costs, demonstrated return on investment, cost of use, training costs, licence and maintenance costs)
+
* No costs for the current version
* Demo: allows the download/utilization of a trial version. If yes, where is it available and what are the trial conditions.
+
* Allows the download/utilization of a trial version
 +
 
  
 
==References==
 
==References==
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===External resources===
 
===External resources===
 +
* Karadeniz Technical University, Faculty of Forestry Forest Management Department website (inactive)
 +
* Baskent EZ, Terzioglu S, Baskaya S 2008. Developing and implementing multiple-use forest management planning in Turkey ,  ENVIRONMENTAL MANAGEMENT  Volume: 42  Issue: 1  Pages: 37-48
 +
* Başkent, E.Z., Başkaya, Ş., and Terzioğlu, S. 2008. Developing and implementing participatory and ecosystem based multiple use forest management planning approach (ETÇAP): Yalnızçam case study, Forest Ecology and Management 256: 798–807

Revision as of 10:07, 29 January 2010

General System description

System name: Ecosystem Based Multiple Use Forest Management Model

Acronym: ETÇAP

Brief overview

ETÇAP is an ecosystem based forest management planning software that allows both evaluating the current estate of a forest ecosystem and preparing specific management plans for a given management objectives under various constraints.

Scope of the system

  • tool encourages decision maker to discover new problems or opportunities by exposing to new information or results
  • tool helps decision makers in recognizing upcoming problems for which solutions have been developed previously
  • tool allows decision maker to actively create new knowledge when faced with a new problem and to develop novel solutions
  • tool allows decision maker to capture knowledge, making it available to decision makers who are seeking solutions from previously solved problems

System origin

• Developed by Emin Zeki BAŞKENT, Sedat KELEŞ and Ali İhsan KADIOĞULLARIETÇAP is in this moment ready to be used in some forest management planning units (Kızılcasu-Cide; Gürgendağ-Edremit; Honaz-Denizli and Akseki-İbradı) in Turkey and will be soon adapted to other Turkish regions after evaluation by the Forest Management Department in Turkish Forest Service


Support for specific issues

Inventory compilation, harvest scheduling, timber-water-carbon production or prediction, soil protection, yield prediction, biodiversity conservation, spatial planning

Support for specific thematic areas of a problem type

  • Timber cruising
  • Silvicultural
  • Certification
  • Conservation
  • Development choices / land use zoning
  • Policy/intervention alternatives
  • Spatial layout of interventions

Capability to support decision making phases

(NOTE I do not quite know what to do with this, as I do not understand it myself, although it seems related to system use)

(Click here to see a more detailed explanation)

  • Intelligence (The current conditions of the forest can be analysed with various management strategies to achieve targets and a spatially configured harvest schedules be prepared.)
  • Design (The simulation tool runs the different management possibilities among the restrictions imposed by the input data to understand forest dynamics.

The optimization tool projects the current state of a forest into a target forest under various management prescriptions with objectives and constraints.)

  • Choice (Heuristic tools are used in order to ensure the spatial layout of the best management option chosen by the manager. )
  • Monitor (Not implemented.)

Related systems

Data and data models

Typical spatial extent of application

The normal spatial application level of ETÇAP is the forest level with various stands. Yet the spatial resolution of the model is the stand, the smallest identifiable unit of forest area.

Forest data input

ETÇAP input information are inventory data that can be imported from files with .xls or .mdb extensions with a specific format. The input data required depends on the characteristics of the stand. Three groups of data are needed for the model; the current area of the stands generated by a GIS software, current status of each stand measured with inventory sheets for per area growth and yield characteristics (in each plot: the plot size, diameters of all stems, ages of some stems, age and dominant height for a number of stems, and ten-last-years growth for some trees) and the other support tables (volume table, empirical yield table, site index table, product assortment table and financial value table) characteristics In order to allow spatial layout of a harvest schedule for visualization and generation of maps, compartments, forest stratifications and analysis areas have to be set and related to each polygon (a sub-compartment =stand) with geographic files

If necessary describe other types of required data (economic, social)

Type of information input from user (via GUI)

Forest management strategies with specific objectives and constraints have to be developed as shown in the user interface. More than one goal may be selected to address multi-objective management of forests. The indicated targets as management objectives are both yield-economic goals and conservation targets.

Models

Forest models

Models implemented in ETÇAP simulate silvicultural treatment schedules according to the stand variables previously given based on both optimization and simulation techniques. Currently ETÇAP has implemented models for the management of either even-aged, uneven-aged, pures or mixed forest stands of any species that have the growth and yield data

Social models

-Not available yet

Decision Support

Definition of management interventions

The user lays out the alternative management prescriptions as sequences of silvicultural treatments; how, when (time of harvest, regeneration methods, thinnings, etc.) and where (a stand or a contiguous group of stands) the treatments could be conducted in order to achieve the previously chosen management targets.

Typical temporal scale of application

Strategic and tactical planning.

Types of decisions supported

  • Management level
    • Strategic decisions
    • Operating control decisions
  • Management function

Decision-making processes and models

  • Traditional simulation
  • Simulated annealing
  • Random ascent
  • Linear programming


Output

Types of outputs

  • Stand level table and graphical outputs showing the temporal changes of its parameters
  • Forest level outputs showing the performance of forest dynamics based on selected performance indicators in various display formats (bar chart, line chart, table format)
  • Forest level map display depicting the long term harvest schedules (regeneration, thinning, and aforestation)

Spatial analysis capabilities

  • integrated capabilities
  • facilitates links to GIS
  • provides standard data import/export formats
  • allows spatial query
  • statistics by area


Abilities to address interdisciplinary, multi-scaled, and political issues

Evaluate interactions between different basic information types (biophysical, economic, social).

System

System requirements

  • Operating Systems: (Windows)
  • Other software needed (GIS, LINDO, Access and other free software development kits)

Architecture and major DSS components

Desktop client-server system of architecture is in place

Usage

Research level use, government use

Computational limitations

No limitation on the number of stands as long as hardware components (RAM and disk space) are not limiting. Time horizon for optimization is about twice the rotation period.

User interface

In-hose developed GUI is available

Documentation and support

No manual is ready now

Installation

  • Level of effort to become functional
  • No costs for the current version
  • Allows the download/utilization of a trial version


References

Cited references


External resources

  • Karadeniz Technical University, Faculty of Forestry Forest Management Department website (inactive)
  • Baskent EZ, Terzioglu S, Baskaya S 2008. Developing and implementing multiple-use forest management planning in Turkey , ENVIRONMENTAL MANAGEMENT Volume: 42 Issue: 1 Pages: 37-48
  • Başkent, E.Z., Başkaya, Ş., and Terzioğlu, S. 2008. Developing and implementing participatory and ecosystem based multiple use forest management planning approach (ETÇAP): Yalnızçam case study, Forest Ecology and Management 256: 798–807