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Free keywords:
Demographic Stochasticity; Diffusion Theory; Evolutionary
Games; Fixation Probability; Weak Selection; Quantitative Biology; Populations and Evolution; MSC 60J60; MSCV91A22; MSC 92D25
Abstract:
We study the fixation probability of a mutant type when introduced into
a resident population. We implement a stochastic competitive Lotka–Volterra model
with two types and intra- and interspecific competition. The model further allows for
stochastically varying population sizes. The competition coefficients are interpreted in
terms of inverse payoffs emerging from an evolutionary game. Since our study focuses
on the impact of the competition values, we assume the same net growth rate for both
types. In this general framework, we derive a formula for the fixation probability
φ
of the mutant type under weak selection. We find that the most important parameter
deciding over the invasion success of the mutant is its death rate due to competition
with the resident. Furthermore, we compare our approximation to results obtained
by implementing population size changes deterministically in order to explore the
parameter regime of validity of our method. Finally, we put our formula in the context
of classical evolutionary game theory and observe similarities and differences to the
results obtained in that constant population size setting.