A simple cellular automaton model for high-level vegetation dynamics
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[1] J. Connell. Diversity in tropical rain forests and coral reefs. , 1978, Science.
[2] Roderick Hunt,et al. Allocating C-S-R plant functional types : a soft approach to a hard problem , 1999 .
[3] R. Hunt,et al. A self‐assembling model of resource dynamics and plant growth incorporating plant functional types , 2001 .
[4] J. P. Grime,et al. Evidence for the Existence of Three Primary Strategies in Plants and Its Relevance to Ecological and Evolutionary Theory , 1977, The American Naturalist.
[5] Claudia Neuhauser,et al. Spatial Dynamics in Model Plant Communities: What Do We Really Know? , 2003, The American Naturalist.
[6] J. P. Grime,et al. Plant Strategies, Vegetation Processes, and Ecosystem Properties , 2006 .
[7] Jianguo Wu,et al. A spatially explicit hierarchical approach to modeling complex ecological systems: theory and applications , 2002 .
[8] J. Molofsky,et al. A New Kind of Ecology? , 2004 .
[9] R. May,et al. Population dynamics and plant community structure: Competition between annuals and perrenials , 1987 .
[10] John F. Weishampel,et al. Simulating vertical and horizontal multifractal patterns of a longleaf pine savanna , 2001 .
[11] Steven F. Railsback,et al. Individual-based modeling and ecology , 2005 .
[12] Jonathan Silvertown,et al. Cellular Automaton Models of Interspecific Competition for Space--The Effect of Pattern on Process , 1992 .
[13] Christophe Lett,et al. Comparison of a cellular automata network and an individual-based model for the simulation of forest dynamics , 1999 .
[14] J. P. Grime,et al. Resource dynamics and vegetation processes: a deterministic model using two-dimensional cellular automata , 1993 .
[15] H. Balzter,et al. Cellular automata models for vegetation dynamics , 1998 .
[16] L. Parrott,et al. Examining the colonization process of exotic species varying in competitive abilities using a cellular automaton model , 2006 .
[17] Thomas M. Smith,et al. Plant functional types : their relevance to ecosystem properties and global change , 1998 .
[18] J. P. Grime,et al. The plant traits that drive ecosystems: Evidence from three continents , 2004 .
[19] G B Ermentrout,et al. Cellular automata approaches to biological modeling. , 1993, Journal of theoretical biology.
[20] Inman Harvey,et al. Fourth European Conference on Artificial Life , 1997 .
[21] S. Higgins,et al. A review of models of alien plant spread. , 1996 .
[22] J. P. Grime,et al. Plant Strategies and Vegetation Processes. , 1980 .
[23] K. Thompson,et al. A new practical tool for deriving a functional signature for herbaceous vegetation , 2004 .
[24] J. P. Grime. Control of species density in herbaceous vegetation , 1973 .
[25] R. Hunt,et al. Resource dynamics and plant growth: a self‐assembling model for individuals, populations and communities , 1997 .
[26] Leah Edelstein,et al. The propagation of fungal colonies: a model for tissue growth , 1982 .
[27] John W. Hearne,et al. An improved cellular automaton model for simulating fire in a spatially heterogeneous Savanna system , 2002 .
[28] J. P. Grime,et al. Competitive Exclusion in Herbaceous Vegetation , 1973, Nature.
[29] Graeme D. Ruxton,et al. The need for biological realism in the updating of cellular automata models , 1998 .
[30] Preben Klarskov Hansen,et al. Using CA model to obtain insight into mechanism of plant population spread in a controllable system: annual weeds as an example , 2003 .
[31] Bruce Hannon,et al. Modeling the spread of the Emerald Ash Borer , 2006 .