Evolutionary games on the lattice: death and birth of the fittest

Eric Foxall, Nicolas Lanchier

Published 2016-05-13Version 1

This paper investigates the long-term behavior of an interacting particle system of interest in the hot topic of evolutionary game theory. Each site of the $d$-dimensional integer lattice is occupied by a player who is characterized by one of two possible strategies. Following the traditional modeling approach of spatial games, the configuration is turned into a payoff landscape that assigns a payoff to each player based on her strategy and the strategy of her neighbors. The payoff is then interpreted as a fitness assuming that players independently update their strategy at rate one by mimicking their neighbor with the largest payoff. The mean-field approximation of this spatial game exhibits the same long-term behavior as the popular replicator equation. Except for a coexistence result that shows an agreement between the process and the mean-field model, our analysis reveals that the two models strongly disagree in a many aspects, showing in particular that the presence of a spatial structure in the form of local interactions plays a key role. More precisely, in the parameter region where both strategies are evolutionary stable in the replicator equation, either one strategy wins or the system fixates in a configuration where both strategies are present for the spatial game. In addition, while defection is always evolutionary stable for the prisoner's dilemma game in the replicator equation, space favors cooperation in our model.