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 [[http://www.easterbrook.ca/steve/2013/01/simple-climate-models-to-play-with-in-the-classroom/|here]]
 or the following papers.
+==== System Dynamics ====
+|  | [[http://citeseerx.ist.psu.edu/viewdoc/download;jsessionid=CB3EA777DE19841D563DC6241FA916B6?doi=10.1.1.497.9850&rep=rep1&type=pdf|Scherer A. & McLean A., (2002) Mathematical models of vaccination, British Medical Bulletin 2002;62 187-199.]] |
+|  | [[http://calculadora2050brasil.epe.gov.br/calculadora.html|Energy scenarios for Brazil (in portuguese)]]|
+==== Cellular Automata ====
 |  | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Berjak2002.pdf|S. G. Berjak,  J. W. Hearne (2002) An improved cellular automaton model for simulating fire in a spatially heterogeneous Savanna system. Ecological Modelling 148(2):133–15}}|
-| | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Sirakoulis2000.pdf|G.Ch Sirakoulis, I. Karafyllidis, A. Thanailakis (2000) A cellular automaton model for the effects of population movement and vaccination on epidemic propagation. Ecological Modelling 133(3): 209–223}}|
 |  | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Beauchemina2005.pdf|C. Beauchemina, J. Samuelb, J. Tuszynskia (2005) A simple cellular automaton model for influenza A viral infections. Journal of Theoretical Biology 232(2) 223–234}}|
-| | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Medeiros2011.pdf|Medeiros, L. C., Castilho, C. A. R., Braga, C., de Souza, W. V., Regis, L., Monteiro, A. M. V. (2011). Modeling the dynamic transmission of dengue fever: investigating disease persistence. PLOS neglected tropical diseases, 5(1), e942.}}|
-| | {{http://www.openabm.org/model/2274/version/2/view| M Janssen and N.D. Rollins (2012). Evolution of cooperation in asymmetric commons dilemmas. Journal of Economic Behavior and Organization, 81: 220-229. Available in CoMSES Computational Model Library).}}|
 | | {{http://www.dpi.inpe.br/gilberto/cursos/papers/White2007.pdf|S. Hoya White, A. Martín del Rey, G. Rodríguez Sánchez(2007), Modeling epidemics using cellular automata. Applied Mathematics and Computation, 186(1):193-202}}|
 | | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Almeida2011.pdf|Almeida, Rodolfo Maduro, and Elbert EN Macau. "Stochastic cellular automata model for wildland fire spread dynamics." Journal of Physics: Conference Series. Vol. 285. No. 1. IOP Publishing, 2011.}}|
@@ Line 56: / Line 61: @@
 | | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Chate1990.pdf|Chate, H. & Manneville, P. (1990). Criticality in cellular automata. Physica D (45), 122-135.}}|
 | | Li, W., Packard, N., & Langton, C. (1990). Transition Phenomena in Cellular Automata Rule Space. Physica D (45), 77-94. |
-| | [[https://en.wikipedia.org/wiki/Belousov–Zhabotinsky_reaction|Belousov–Zhabotinsky reaction]]|
 | | Colasanti, R. L., R. Hunt, and L. Watrud. "A simple cellular automaton model for high-level vegetation dynamics." Ecological Modelling 203.3 (2007): 363-374.|
-|  | [[http://citeseerx.ist.psu.edu/viewdoc/download;jsessionid=CB3EA777DE19841D563DC6241FA916B6?doi=10.1.1.497.9850&rep=rep1&type=pdf|Scherer A. & McLean A., (2002) Mathematical models of vaccination, British Medical Bulletin 2002;62 187-199.]] |
+| | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Yassemi2008.pdf|S. Yassemi, S. Dragićevića, M. Schmidt(2008), Design and implementation of an integrated GIS-based cellular automata model to characterize forest fire behaviour
-|  | Pe'er et al. Virtual Corridors for Conservation Management, Conservation Biology (2005): 1997–2003 |
+, Ecological Modelling, 210(1–2), 71–84}}|
-|  | Garcia et al. Predicting evolution of insect resistance to transgenic crops in within field refuge configurations, based on larval movement. Ecol. Complex. 28, 94–103 (2016).|
+| | {{http://pdf.blucher.com.br.s3-sa-east-1.amazonaws.com/designproceedings/sigradi2016/450.pdf| Araujo and Celani (20166), Exploring Weaire-Phelan through Cellular Automata: A proposal for a structural variance-producing engine}}|
-|  | Malaquias et al. Larval Dispersal of Spodoptera frugiperda Strains on Bt Cotton: A Model for Understanding Resistance Evolution and Consequences for its Management. Scientific reports. 2017 Nov 23;7(1):16109.|
-|  | Brown, C.; Bakam, I.; Smith. P.; Matthews, R.B., (2016) An agent-based modelling approach to evaluate factors influencing bioenergy crop adoption in north-east Scotland., Global Change Biology Bioenergy, 8, 226-244.|
-|  | [[http://calculadora2050brasil.epe.gov.br/calculadora.html|Energy scenarios for Brazil (in portuguese)]]|
 |  | [[http://link.aps.org/pdf/10.1103/PhysRevE.58.1425|Rickert, M., Nagel, K., Schreckenberg, M. and Latour, A., 1996. Two lane traffic simulations using cellular automata. Physica A: Statistical Mechanics and its Applications, 231(4), pp.534-550.]]|
 |  | [[https://pdfs.semanticscholar.org/a522/5a5633d0ce89c913a65c2e6cde72f808e95f.pdf|White, R. and Engelen, G., 1993. Cellular automata and fractal urban form: a cellular modelling approach to the evolution of urban land-use patterns. Environment and planning A, 25(8), pp.1175-1199.]] |
@@ Line 74: / Line 75: @@
 | | [[https://pdfs.semanticscholar.org/4f78/2bcb7bf2c0d4e1a210a41b80a4f664efc9f8.pdf|Bersini, H. and Detours, V., 1994, July. Asynchrony induces stability in cellular automata based models. In Artificial Life IV (pp. 382-387). MIT Press, MA.]]|
-===== Papers for Final Projects: Secondary Choices =====
+==== Agent-based Modeling ====
-You can also choose from the following papers if you did not find a suitable paper in the above list.
+| | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Medeiros2011.pdf|Medeiros, L. C., Castilho, C. A. R., Braga, C., de Souza, W. V., Regis, L., Monteiro, A. M. V. (2011). Modeling the dynamic transmission of dengue fever: investigating disease persistence. PLOS neglected tropical diseases, 5(1), e942.}}|
+| | {{http://www.openabm.org/model/2274/version/2/view| M Janssen and N.D. Rollins (2012). Evolution of cooperation in asymmetric commons dilemmas. Journal of Economic Behavior and Organization, 81: 220-229. Available in CoMSES Computational Model Library).}}|
 | | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Bandini2007.pdf|S Bandini, F Celada, S Manzoni, G Vizzari (2007). Modelling the immune system: the case of situated cellular agents, Natural Computing, 6(1):19-32.}}|
-| | {{http://www.dpi.inpe.br/gilberto/cursos/papers/Yassemi2008.pdf|S. Yassemi, S. Dragićevića, M. Schmidt(2008), Design and implementation of an integrated GIS-based cellular automata model to characterize forest fire behaviour
+|  | Pe'er et al. Virtual Corridors for Conservation Management, Conservation Biology (2005): 1997–2003 |
-, Ecological Modelling, 210(1–2), 71–84}}|
+|  | Garcia et al. Predicting evolution of insect resistance to transgenic crops in within field refuge configurations, based on larval movement. Ecol. Complex. 28, 94–103 (2016).|
-| | {{http://pdf.blucher.com.br.s3-sa-east-1.amazonaws.com/designproceedings/sigradi2016/450.pdf| Araujo and Celani (20166), Exploring Weaire-Phelan through Cellular Automata: A proposal for a structural variance-producing engine}}|
+|  | Malaquias et al. Larval Dispersal of Spodoptera frugiperda Strains on Bt Cotton: A Model for Understanding Resistance Evolution and Consequences for its Management. Scientific reports. 2017 Nov 23;7(1):16109.|
+|  | Brown, C.; Bakam, I.; Smith. P.; Matthews, R.B., (2016) An agent-based modelling approach to evaluate factors influencing bioenergy crop adoption in north-east Scotland., Global Change Biology Bioenergy, 8, 226-244.|

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