Evolutionary Behaviour, Trade-Offs and Cyclic and Chaotic Population Dynamics

Autor:	Andrew White, Roger G. Bowers, Andrew Hoyle
Rok vydání:	2010
Předmět:	General Mathematics Population Dynamics Immunology Population Chaotic Models Biological General Biochemistry Genetics and Molecular Biology Quantitative Trait Heritable Control theory Attractor Computer Simulation Statistical physics Selection Genetic Algebraic number Logistic function education General Environmental Science Mathematics Population Density Pharmacology education.field_of_study General Neuroscience Dynamics (mechanics) Trade offs Biological Evolution Expression (mathematics) Computational Theory and Mathematics Mutation Genetic Fitness General Agricultural and Biological Sciences Algorithms
Zdroj:	Bulletin of Mathematical Biology. 73:1154-1169
ISSN:	1522-9602 0092-8240
DOI:	10.1007/s11538-010-9567-7
Popis:	Many studies of the evolution of life-history traits assume that the underlying population dynamical attractor is stable point equilibrium. However, evolutionary outcomes can change significantly in different circumstances. We present an analysis based on adaptive dynamics of a discrete-time demographic model involving a trade-off whose shape is also an important determinant of evolutionary behaviour. We derive an explicit expression for the fitness in the cyclic region and consequently present an adaptive dynamic analysis which is algebraic. We do this fully in the region of 2-cycles and (using a symbolic package) almost fully for 4-cycles. Simulations illustrate and verify our results. With equilibrium population dynamics, trade-offs with accelerating costs produce a continuously stable strategy (CSS) whereas trade-offs with decelerating costs produce a non-ES repellor. The transition to 2-cycles produces a discontinuous change: the appearance of an intermediate region in which branching points occur. The size of this region decreases as we move through the region of 2-cycles. There is a further discontinuous fall in the size of the branching region during the transition to 4-cycles. We extend our results numerically and with simulations to higher-period cycles and chaos. Simulations show that chaotic population dynamics can evolve from equilibrium and vice-versa.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_dedup___::7717dd75082a508dcb5d56101aff7ea5 https://doi.org/10.1007/s11538-010-9567-7 Zobrazit plný text záznamu Full text from SpringerLink