Abstract
This work takes place in the framework of GEODIFF project (funded by CNRS) and deals with the general issue of the social behavior modeling of pest insects with a particular focus on Bark Beetles. Bark Beetles are responsible for pine trees devastation in North America since 2005. In order to stem the problem and to apply an adapted strategy, one should be able to predict the evolution of the population of Bark Beetles. More precisely, a model taking into account a given population of insects (a colony) interacting with its environment, the forest ecosystem, would be very helpful. In a previous work, we aimed to model diffusive phenomenons across the environment using a simple reactive Multi-agent System. Bark beetle use pheromones as a support for recruitment of other bark beetles in the neighborhood in order to achieve a mass attack over a tree. They are first attracted by the ethanol or other phytopheromones emitted by a sick, stressed or dead tree and reinforce the presence of other individuals amongst the targeted tree. Both ethanol and semiochemicals are transported through the forest thanks to the wind, thermic effects and this advection phenomenon is modulated by the topology of the environment, tree and other obstacles distribution. In other words, the environment is involved in the process of a bark beetle attack. The first modeling we used to tackle our objective was not spatially explicit as long as free space propagation only was taken into account (isotropic phenomenon) with no constraint imposed by the environment such as wind. This article is intended to take into account such physical phenomenons and push the modeling one step further by providing predictions driven by measures provided by a Geographical Information System.
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Notes
- 1.
\(D(\phi , r) = D_{\varPhi }, \forall r \in R\).
- 2.
\(\phi (r, t + h) = \phi (r, t) + h \frac{\partial \phi (r, t)}{\partial t}\) with \(h = 1\).
- 3.
\(attractiveness[x][y] = MIN\).
- 4.
\(attractiveness[x][y] = MAX\).
References
Berryman, A.A., Millstein, J.A.: Population Analysis System, Pullman edn. Washington (1994). Version 4.0
Ferber, J.: Multi-Agent Systems: An Introduction to Distributed Artificial Intelligence. Addison-Wesley (1999)
Drogoul, A.: Résolution Collective de Problèmes: Une étude de l’émergence de structures d’organisations dans les systèmes multi-agents. Ph.D. thesis, Université Paris VI (1993)
Rouchier, J. In: Systèmes multi-agents et modélisation de systèmes sociaux, Hermes Science, pp. 285–299 (2002)
Bentz, B.: Climate change and bark beetles of the western united states and canada: direct and indirect effects. BioScience 8(60), 602–613 (2010). doi:10.1525/bio.2010.60.8.6
Robins, J.: Bark Beetles Kill Millions of Acres of Trees in West, New York Times, 17 November 2008
Amouroux, E., Chu, T.-Q., Boucher, A., Drogoul, A.: GAMA: an environment for implementing and running spatially explicit multi-agent simulations. In: Ghose, A., Governatori, G., Sadananda, R. (eds.) PRIMA 2007. LNCS, vol. 5044, pp. 359–371. Springer, Heidelberg (2009)
Taillandier, P., Vo, D.-A., Amouroux, E., Drogoul, A.: GAMA: a simulation platform that integrates geographical information data, agent-based modeling and multi-scale control. In: Desai, N., Liu, A., Winikoff, M. (eds.) PRIMA 2010. LNCS, vol. 7057, pp. 242–258. Springer, Heidelberg (2012)
Drogoul, A., Amouroux, E., Caillou, P., Gaudou, B., Arnaud, G., Marilleau, N., Taillander, P., Vavasseur, M., Duc-An, V., Jean-Daniel, Z.: Gama: multi-level and complex environment for agent-based models and simulations. In: Proceedings of the 2013 International Conference on Autonomous Agents and Multi-agent Systems, pp. 1361–1362 (2013)
Picard, D., Histace, A., Desseroit, M.C.: Joint MAS-PDE modeling of forest pest insect dynamics: analysis of the bark beetle’s behavior (2013)
Byers, J.A.: Behavioral mechanisms involved in reducing competition in bark beetles. HOLARCT. ECOL. 12, 466–476 (1989)
Bakke, A.: Using pheromones in the management of bark beetle outbreaks. In: Patterns of Interaction with Host Trees, pp. 371–377 (1991)
Harrington, T.C.: Ecology and evolution of mycophagous bark beetles and their fungal partners. In: Press, O.U., Vega, F.E., Blackwell, M. (eds.) Ecological and Evolutionary Advances in Insect-Fungal Associations, pp. 257–291 (2005)
Langlois, P., Daudé, E.: Concepts et modélisation de la diffusion géographique: cybergeo. Eur. J. Geogr. (2007). http://www.cybergeo.eu/index2898.html
Stam, J.: Real-time fluid dynamics for games. In: Proceedings of the Game Developer Conference (2003)
West, M.: Practical fluid dynamics: part 1. In: Game Developer Magazine (2008)
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Cazin, N., Histace, A., Picard, D., Gaudou, B. (2015). On the Joint Modeling of the Behavior of Social Insects and Their Interaction with Environment by Taking into Account Physical Phenomena Like Anisotropic Diffusion. In: Bajo, J., et al. Highlights of Practical Applications of Agents, Multi-Agent Systems, and Sustainability - The PAAMS Collection. PAAMS 2015. Communications in Computer and Information Science, vol 524. Springer, Cham. https://doi.org/10.1007/978-3-319-19033-4_13
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