Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming

This study attempts to model alpine tundra vegetation dynamics in a tundra region in the Qinghai Province of China in response to global warming. We used Raster-based cellular automata and a Geographic Information System to study the spatial and temporal vegetation dynamics. The cellular automata mo...

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Main Authors:	Zhang, Yanqing A., Peterman, Michael R., Aun, Dorin L., Zhang, Yanming
Format:	Report
Language:	unknown
Published:	2008
Subjects:	Antarctic and Alpine Research Arctic Tundra
Online Access:	http://ir.nwipb.ac.cn/handle/363003/1239 http://210.75.249.4/handle/363003/15075

id	ftchinacascnwipb:oai:210.75.249.4:363003/15075
record_format	openpolar
spelling	ftchinacascnwipb:oai:210.75.249.4:363003/15075 2023-05-15T14:14:17+02:00 Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming Zhang, Yanqing A. Peterman, Michael R. Aun, Dorin L. Zhang, Yanming 2008-02-01 http://ir.nwipb.ac.cn/handle/363003/1239 http://210.75.249.4/handle/363003/15075 unknown ARCTIC ANTARCTIC AND ALPINE RESEARCH Zhang Yanqing A.,Peterman Michael R.,Aun Dorin L.,Zhang Yanming.Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming.ARCTIC ANTARCTIC AND ALPINE RESEARCH,2008,40(1):256-263 http://ir.nwipb.ac.cn/handle/363003/1239 http://210.75.249.4/handle/363003/15075 期刊论文 2008 ftchinacascnwipb 2023-03-26T20:24:43Z This study attempts to model alpine tundra vegetation dynamics in a tundra region in the Qinghai Province of China in response to global warming. We used Raster-based cellular automata and a Geographic Information System to study the spatial and temporal vegetation dynamics. The cellular automata model is implemented with IDRISI's Multi-Criteria Evaluation functionality to simulate the spatial patterns of vegetation change assuming certain scenarios of global mean temperature increase over time. The Vegetation Dynamic Simulation Model calculates a probability surface for each vegetation type, and then combines all vegetation types into a composite map, determined by the maximum likelihood that each vegetation type should distribute to each raster unit. With scenarios of global temperature increase of I to 3 degrees C, the vegetation types such as Dry Kobresia Meadow and Dry Potentilla Shrub that are adapted to warm and dry conditions tend to become more dominant in the study area. This study attempts to model alpine tundra vegetation dynamics in a tundra region in the Qinghai Province of China in response to global warming. We used Raster-based cellular automata and a Geographic Information System to study the spatial and temporal vegetation dynamics. The cellular automata model is implemented with IDRISI's Multi-Criteria Evaluation functionality to simulate the spatial patterns of vegetation change assuming certain scenarios of global mean temperature increase over time. The Vegetation Dynamic Simulation Model calculates a probability surface for each vegetation type, and then combines all vegetation types into a composite map, determined by the maximum likelihood that each vegetation type should distribute to each raster unit. With scenarios of global temperature increase of I to 3 degrees C, the vegetation types such as Dry Kobresia Meadow and Dry Potentilla Shrub that are adapted to warm and dry conditions tend to become more dominant in the study area. Report Antarctic and Alpine Research Arctic Tundra Northwest Institute of Plateau Biology: NWIPB OpenIR (Chinese Academy of Sciences)
institution	Open Polar
collection	Northwest Institute of Plateau Biology: NWIPB OpenIR (Chinese Academy of Sciences)
op_collection_id	ftchinacascnwipb
language	unknown
description	This study attempts to model alpine tundra vegetation dynamics in a tundra region in the Qinghai Province of China in response to global warming. We used Raster-based cellular automata and a Geographic Information System to study the spatial and temporal vegetation dynamics. The cellular automata model is implemented with IDRISI's Multi-Criteria Evaluation functionality to simulate the spatial patterns of vegetation change assuming certain scenarios of global mean temperature increase over time. The Vegetation Dynamic Simulation Model calculates a probability surface for each vegetation type, and then combines all vegetation types into a composite map, determined by the maximum likelihood that each vegetation type should distribute to each raster unit. With scenarios of global temperature increase of I to 3 degrees C, the vegetation types such as Dry Kobresia Meadow and Dry Potentilla Shrub that are adapted to warm and dry conditions tend to become more dominant in the study area. This study attempts to model alpine tundra vegetation dynamics in a tundra region in the Qinghai Province of China in response to global warming. We used Raster-based cellular automata and a Geographic Information System to study the spatial and temporal vegetation dynamics. The cellular automata model is implemented with IDRISI's Multi-Criteria Evaluation functionality to simulate the spatial patterns of vegetation change assuming certain scenarios of global mean temperature increase over time. The Vegetation Dynamic Simulation Model calculates a probability surface for each vegetation type, and then combines all vegetation types into a composite map, determined by the maximum likelihood that each vegetation type should distribute to each raster unit. With scenarios of global temperature increase of I to 3 degrees C, the vegetation types such as Dry Kobresia Meadow and Dry Potentilla Shrub that are adapted to warm and dry conditions tend to become more dominant in the study area.
format	Report
author	Zhang, Yanqing A. Peterman, Michael R. Aun, Dorin L. Zhang, Yanming
spellingShingle	Zhang, Yanqing A. Peterman, Michael R. Aun, Dorin L. Zhang, Yanming Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming
author_facet	Zhang, Yanqing A. Peterman, Michael R. Aun, Dorin L. Zhang, Yanming
author_sort	Zhang, Yanqing A.
title	Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming
title_short	Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming
title_full	Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming
title_fullStr	Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming
title_full_unstemmed	Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming
title_sort	cellular automata: simulating alpine tundra vegetation dynamics in response to global warming
publishDate	2008
url	http://ir.nwipb.ac.cn/handle/363003/1239 http://210.75.249.4/handle/363003/15075
genre	Antarctic and Alpine Research Arctic Tundra
genre_facet	Antarctic and Alpine Research Arctic Tundra
op_relation	ARCTIC ANTARCTIC AND ALPINE RESEARCH Zhang Yanqing A.,Peterman Michael R.,Aun Dorin L.,Zhang Yanming.Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming.ARCTIC ANTARCTIC AND ALPINE RESEARCH,2008,40(1):256-263 http://ir.nwipb.ac.cn/handle/363003/1239 http://210.75.249.4/handle/363003/15075
_version_	1766286833860214784

Cellular automata: Simulating alpine tundra vegetation dynamics in response to global warming

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