An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model
An algorithm for decision making on forest management in the Global Forest Model (G4M) is developed. The algorithm provides harvesting of a specified amount of wood in countries. Adequateness of the algorithm is demonstrated on example of Ukraine, Poland, Byelorussia and Russia. Розроблен алгоритм п...
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Інститут проблем штучного інтелекту МОН України та НАН України
2010
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| Cite this: | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model / M.I. Gusti // Штучний інтелект. — 2010. — № 4. — С. 45-49. — Бібліогр.: 6 назв. — англ. |
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| citation_txt | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model / M.I. Gusti // Штучний інтелект. — 2010. — № 4. — С. 45-49. — Бібліогр.: 6 назв. — англ. |
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| description | An algorithm for decision making on forest management in the Global Forest Model (G4M) is developed. The algorithm provides harvesting of a specified amount of wood in countries. Adequateness of the algorithm is demonstrated on example of Ukraine, Poland, Byelorussia and Russia.
Розроблен алгоритм прийняття рішень щодо лісокористування в глобальній моделі лісу (G4M). Алгоритм забезпечує заготівлю заданої кількості деревини по країнах. Продемонстровано адекватність алгоритму на прикладі України, Польщі, Білорусі та Росії.
Разработан алгоритм принятия решений относительно лесопользования в глобальной модели леса (G4M). Алгоритм обеспечивает заготовление заданного количества древесины по странам. Продемонстрирована адекватность алгоритма на примере Украины, Польши, Белоруссии и России.
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«Штучний інтелект» 4’2010 45
2G
UDC 519.6
M.I. Gusti
National Polytechnic University, Lviv, Ukraine
International Institute for Applied Systems Analysis, Laxenburg, Austria
mykola.gusti@yahoo.com
An Algorithm for Simulation of Forest
Management Decisions in the Global Forest Model
An algorithm for decision making on forest management in the Global Forest Model (G4M) is developed.
The algorithm provides harvesting of a specified amount of wood in countries. Adequateness of the algorithm
is demonstrated on example of Ukraine, Poland, Byelorussia and Russia.
Introduction
Climate extreme events the people are facing the last decade more and more often [1]
are associated with human induced climate change [2]. Mitigation of climate change
requires substantial reduction of greenhouse gas emissions to the atmosphere, as well as
sequestration of carbon dioxide (one of the most influential greenhouse gas) in ecosystems.
Reduction of emissions from deforestation and forest degradation (REDD) is expected to
be included in the next climate agreement, in particular REDD was considered at the recent
climate change negations in Copenhagen in 2009 [3].
There is a need for a model allowing simulation of different forest management options
and corresponding carbon flows in order to assess effectiveness of forest management miti-
gation options. In contrast to local scale models we propose a global model assuring similar
accounting approach across countries and thus making the countries comparable.
We improved the Global Forest Model (G4M), which has been developed at the Inter-
national Institute for Applied Systems Analysis for assessing policies aimed at reduction of
deforestation and stimulation of afforestation [4], [5]. We supplied G4M with a forest ma-
nagement module1 and an algorithm simulating decision making on forest management to
satisfy wood demand.
The objective of this paper is to develop an algorithm for simulation of forest
management decisions that allow production of demanded amount of wood for usage in the
Global Forest Model.
Structure of the global forest model
The G4M is a geographically explicit agent-based model that simulates decisions
made by virtual land owners on deforestation and afforestation taking into account pro-
fitability of forestry and agriculture. Considered version of the model operates on a regular
grid of 0,5×0,5 decimal degree2. Forest parameters in each cell are initialized using global
geographic datasets – the forest area with global landcover (GLC 2000), forest biomass
with a product obtained from FAO data, agriculture suitability, protected land where lan-
duse-change is not allowed, etc. The land use change decisions are estimated for each grid-
cell [6].
1 The forest management module is developed by Georg Kindermann, International Institute for Applied
Systems Analysis, Austria.
2 In fact the resolution depends on input data resolution and computational resources.
Gusti M.I.
«Искусственный интеллект» 4’2010 46
2G
Deforestation occurs if price of agricultural land (that mimics the net present value of
agriculture) together with profit from selling wood obtained from clearing the forest is
greater than the net present value (NPV) of forestry. On opposite, afforestation occurs if
there is land that can be afforested, the environmental conditions are suitable and the
forestry NPV is greater than the price of agricultural land [6].
By giving a value to the carbon stored in existing forests or accumulated in planted
forests, e.g. carbon tax for lost carbon in case of deforestation or payments for carbon
accumulated additionally in forest ecosystem in case of a/re-fforestation we can increase
forestry NPV and thus stimulate forest owners to decrease deforestation and increase
afforestation [5], [6].
The model is widely used for evaluation of policies aimed at reduction of deforestation
and forest degradation (REDD) on global, regional [4] or country scale [5].
Forest management module
The forest management module simulates forestry on a scale of forest. It contains
a generic forest growth function, allows creation of a forest with specified environmental
and management parameters (growth function parameters, mean annual increment for a
normal forest1 – MAI, stocking degree – SD, rotation length – RL, thinning, harvest losses,
forest area and age structure information). Forest is represented with a set of forest plots of
(N = RL+1) N age classes (one year step) and of different area as specified in the age struc-
ture information derived from country forestry statistics. If the age structure is not speci-
fied the forest management module creates a normal forest. The forest management
module provides thinning and harvest according to the specified parameters bringing forest
to “normal” state gradually. The forest management module also determines RL that is opti-
mal for getting maximal mean annual increment and maximal sustainable harvest every year
(RLMAI), getting maximal biomass (RLmaxBm), or keep current biomass (RLBm) for particu-
lar growth conditions (MAI) and management type (SD and thinning).
Simulation of forest management decision-making
In each grid cell where MAI and land area are greater than zero, and environmental
conditions are suitable for growing forest, two virtual forests are created using the forest
management module – an existing forest, which matches observed aboveground biomass
(Cab modeled with Cfmab) and forest area, and a new forest with zero area that probably will
be planted during the simulation (fig. 1).
A set of forest parameters is initialized iteratively using geographically explicit or
country specific information. Increment is determined using a map of potential net primary
production and translated into MAI. MAI was scaled at country level to match MCPFE (The
Ministerial Conference on the Protection of Forests in Europe) data. Age structure and stocking
degree are used as additional information for adjusting MAI. If stocking degree of forest
modeled with a given age structure (country average) in a cell is greater than 1,05, age
structure of the modeled forest is shifted iteratively by a few age classes towards older forest. If
stocking degree of forest modeled in a cell is smaller than 0,5, age structure of the modeled
forest is shifted iteratively by a few age classes towards younger forest. It is required that the
shifts are symmetrical to keep country average age structure close to statistical value. If the age
structure shift distribution within a country is skewed towards older forest, the country’s
average MAI is increased iteratively. If the age structure shift distribution within a country is
skewed towards younger forest, country MAI is decreased iteratively.
1 Forest which consists of forest plots of all age classes (up to RL) of equal area.
An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model
«Штучний інтелект» 4’2010 47
2G
Figure 1 – Initialization of virtual forests in the grid cells
In case of non-uniform age structure stocking degree is determined as a relation of
modeled biomass to the observed biomass. If age structure information is not available,
stocking degree is set to one.
Six forest management types (FMtype) that influence further forest management
decisions are identified:
For Agri
For Agri
For Agri
For Agri
2, 0 NPV NPV
1, 0 NPV NPV
0, 0
1, 0 NPV NPV
2, 0 NPV NPV
3, 1
map
map
map
type
map
map
map
if FM MAI MAI
if FM MAI MAI
if FM MAI MAI
FM
if FM MAI MAI
if FM MAI MAI
if FM MAI MAI
− = ∧ ≤ ∧ ≤− = ∧ ≤ ∧ > = ∧ >= = ∧ ≤ ∧ ≤
= ∧ ≤ ∧ >
= ∧ >
In the above expression FMmap
1 is a map indicating that a particular cell contains
managed or unmanaged forest, NPVFor and NPVAgri are net present values of forestry and
agriculture respectively. MAI is average mean annual increment in country considered.
Forests with FMtype>0 are used for wood production (are managed). Rotation length
of managed forests is set to RLMAI, RLBm or RLmaxBm depending on whether wood harvest
within a country is smaller, equal or greater than domestic wood demand (RLMAI allows
1 Derived from FAO data by Georg Kindermann, International Institute for Applied Systems Analysis (Austria).
FM map
MAI map
Cab map
Timber price map
AgriLand price
map
Forest area map
Harvest losses
(country)
Wood demand
(country)
Age structure inf.
(country)
New forest
(MAI, Area=0)
Existing forest
(MAI, Area,Cfmab,SD,RL,FMtype,Harvest,AgeStruct)
Gusti M.I.
«Искусственный интеллект» 4’2010 48
2G
maximal annual sustainable harvest and usually is the shortest considered rotation, RLBm
allows keeping current biomass in forest, RLmaxBm allows accumulation of biomass in
forest and usually is the longest considered rotation). If RLBm is smaller that RLMAI we use
RLMAI to avoid transition effect resulting in temporal decrease of harvest even if the
rotation length is changed to RLMAI.
Every simulation year all cells are processed one by one. In the input file, which
contains data for each grid cell, the cells are sorted by countries, then descending by MAI,
amount of carbon in aboveground biomass, forest area, population density and agriculture
suitability. Thus productive forests of larger area and closer to populated places are
processed first. Harvested wood in a cell is a sum of final harvest, pre-final harvest
(thinning) and wood obtained from deforestation. A sum of harvested wood in a country is
compared to domestic demand in the country. If demand is greater than supply by more
than 2 %, rotation length of forest in cells (that belong to the considered country) is
decreased to RLMAI one by one until demand is satisfied. If after processing all cells in the
country, demand is still greater than supply by 2 %, unmanaged forest (FMtype ≤ 0) is turned
to managed (FMtype > 0), cells with population >0 or FMtype= 0 and – 1 are taken first.
If harvest in a country is greater than demand by 2 % rotation length of less productive
forests (0 < FMtype < 3) is increased gradually (five-year time step) up to RLmaxBm. If after
processing all cells in the country, harvest is still greater than demand by 3 %, RL of forests in
the country with FMtype > 0 is increased gradually up to RLmaxBm until the 3 % threshold is
reached. Forest management type is changed to unmanaged if the supply-demand
difference is more than 5 % after the previous iterations (FMtype: 1, 2 → – 2, – 1) or if the
difference is still higher than 5 % productive forests are affected as well (FMtype 3 → 0).
8.0E+06
1.0E+07
1.2E+07
1.4E+07
1.6E+07
1.8E+07
2.0E+07
1991 1993 1995 1997 1999 2001 2003 2005
8.0E+06
1.3E+07
1.8E+07
2.3E+07
2.8E+07
3.3E+07
3.8E+07
4.3E+07
1991 1993 1995 1997 1999 2001 2003 2005
a b
6.0E+06
6.5E+06
7.0E+06
7.5E+06
8.0E+06
8.5E+06
9.0E+06
9.5E+06
1.0E+07
1.1E+07
1991 1993 1995 1997 1999 2001 2003 2005
1.1E+08
1.6E+08
2.1E+08
2.6E+08
3.1E+08
3.6E+08
1991 1993 1995 1997 1999 2001 2003 2005
c d
Figure 2 – Wood production in Ukraine (a), Poland (b), Byelorussia (c) and Russia (d) in 1990 – 2005
according to the FAO statistics (rectangles) with 5 % errorbar and simulated harvest (triangles)
An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model
«Штучний інтелект» 4’2010 49
2G
In order to follow expansion of populated cells we check every ten years at the
beginning of forest management adjustment whether harvest deviates from demand by
more than ±12 %. If harvest is greater than demand by 12 % and recently depopulated cell
contains managed forest, the forest is turned to unmanaged. The forest management type is
changed as well (FMtype: 1, 2, 3 → – 2, – 1, 0). If harvest is smaller than demand by 12 %
and recently populated cell contains unmanaged forest, the forest is turned to managed
(used). The forest management type is changed respectively (FMtype: – 2, – 1, 0 → 1, 2, 3).
We applied the algorithm for simulating forest management decisions for getting
statistical wood harvest in 1990 – 2005 in Ukraine (fig. 2a) and neighbor countries – Po-
land (fig. 2b), Byelorussia (fig. 2c) and Russia (fig. 2d). The maximal difference between
modeled and statistical data is 5 %. Increasing wood harvest is modeled with higher precision
– maximal difference on upward parts of the graphs is less than 2 % In general, the harvest
initialized by the algorithm matches the statistical data very well.
Conclusions
The algorithm considered in the paper allows simulation of decision making on forest
management on a forest scale that leads to production of specified amount of wood on a
country scale. If the input data on domestic wood production statistics, deforestation rate
and forest resources are consistent the simulation of forest management decisions using the
algorithm is plausible. The Global Forest Model supplied with the forest management
module and the algorithm can be used for a versatile REDD policy assessment.
Literature
1. Observations: Surface and Atmospheric Climate Change / K.E. Trenberth, P.D. Jones, P. Ambenje [et al.] //
Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth
Assessment Report of the Intergovernmental Panel on Climate Change / Solomon, S., D. Qin, M. Manning, Z.
et al. (Eds.) – Cambridge University Press. – Cambridge, United Kingdom and New York, NY, USA, 2007.
2. Changes in Atmospheric Constituents and in Radiative Forcing / P. Forster, V. Ramaswamy, P. Artaxo [et al.] //
Climate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment
Report of the Intergovernmental Panel on Climate Change / Solomon, S., D. Qin, M. Manning, Z. et al. (Eds.) –
Cambridge University Press, Cambridge, United Kingdom and New York, NY, USA, 2007.
3. Copenhagen Accord. Decision 2/CP.15. / Decision at the 15th Session of the Conference of the Parties
(COP15) // The United Nations Climate Change Conference, Copenhagen. – 2009.
4. Global cost estimates of reducing carbon emissions through avoided deforestation / G. Kindermann,
Obersteiner M., Sohngen B., et al // PNAS. – 2008. – Vol. 105, № 30. – P. 10302-10307.
5. Gusti M. How much additional carbon can be stored in forests if economic measures are used and how
much could it cost? / M. Gusti, P. Havlik, M. Obersteiner // Research Reports of the National University
of Bioresources and Nature Management of Ukraine. – Issue 135.
6. Predicting the Deforestation–Trend under Different Carbon–Prices / G. Kindermann, M. Obersteiner, E. Rametsteiner
and McCallcum I // Carbon Balance and Management. – 2006. – P. 1-15; doi:10.1186/1750-0680-1-15
М.І. Густі
Алгоритм для імітаційного моделювання рішень щодо лісокористування в глобальній моделі лісу
Розроблен алгоритм прийняття рішень щодо лісокористування в глобальній моделі лісу (G4M). Алгоритм
забезпечує заготівлю заданої кількості деревини по країнах. Продемонстровано адекватність алгоритму на
прикладі України, Польщі, Білорусі та Росії.
М.И. Густи
Алгоритм для имитационного моделирования решений относительно лесопользования в глобальной
модели леса
Разработан алгоритм принятия решений относительно лесопользования в глобальной модели леса (G4M).
Алгоритм обеспечивает заготовление заданного количества древесины по странам. Продемонстрирована
адекватность алгоритма на примере Украины, Польши, Белоруссии и России.
Статья поступила в редакцию 21.06.2010.
|
| id | nasplib_isofts_kiev_ua-123456789-58342 |
| institution | Digital Library of Periodicals of National Academy of Sciences of Ukraine |
| issn | 1561-5359 |
| language | English |
| last_indexed | 2025-11-28T23:17:27Z |
| publishDate | 2010 |
| publisher | Інститут проблем штучного інтелекту МОН України та НАН України |
| record_format | dspace |
| spelling | Gusti, M.I. 2014-03-22T15:49:36Z 2014-03-22T15:49:36Z 2010 An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model / M.I. Gusti // Штучний інтелект. — 2010. — № 4. — С. 45-49. — Бібліогр.: 6 назв. — англ. 1561-5359 https://nasplib.isofts.kiev.ua/handle/123456789/58342 519.6 An algorithm for decision making on forest management in the Global Forest Model (G4M) is developed. The algorithm provides harvesting of a specified amount of wood in countries. Adequateness of the algorithm is demonstrated on example of Ukraine, Poland, Byelorussia and Russia. Розроблен алгоритм прийняття рішень щодо лісокористування в глобальній моделі лісу (G4M). Алгоритм забезпечує заготівлю заданої кількості деревини по країнах. Продемонстровано адекватність алгоритму на прикладі України, Польщі, Білорусі та Росії. Разработан алгоритм принятия решений относительно лесопользования в глобальной модели леса (G4M). Алгоритм обеспечивает заготовление заданного количества древесины по странам. Продемонстрирована адекватность алгоритма на примере Украины, Польши, Белоруссии и России. en Інститут проблем штучного інтелекту МОН України та НАН України Штучний інтелект Алгоритмическое и программное обеспечение параллельных вычислительных интеллектуальных систем An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model Алгоритм для імітаційного моделювання рішень щодо лісокористування в глобальній моделі лісу Алгоритм для имитационного моделирования решений относительно лесопользования в глобальной модели леса Article published earlier |
| spellingShingle | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model Gusti, M.I. Алгоритмическое и программное обеспечение параллельных вычислительных интеллектуальных систем |
| title | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model |
| title_alt | Алгоритм для імітаційного моделювання рішень щодо лісокористування в глобальній моделі лісу Алгоритм для имитационного моделирования решений относительно лесопользования в глобальной модели леса |
| title_full | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model |
| title_fullStr | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model |
| title_full_unstemmed | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model |
| title_short | An Algorithm for Simulation of Forest Management Decisions in the Global Forest Model |
| title_sort | algorithm for simulation of forest management decisions in the global forest model |
| topic | Алгоритмическое и программное обеспечение параллельных вычислительных интеллектуальных систем |
| topic_facet | Алгоритмическое и программное обеспечение параллельных вычислительных интеллектуальных систем |
| url | https://nasplib.isofts.kiev.ua/handle/123456789/58342 |
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