starpg10_fast_cfix_T05.csv from The effect of network topology on optimal exploration strategies and the evolution of cooperation in a mobile population

We model a mobile population interacting over an underlying spatial structure using a Markov movement model. Interactions take the form of public goods games, and can feature an arbitrary group size. Individuals choose strategically to remain at their current location or to move to a neighbouring location, depending upon their exploration strategy and the current composition of their group. This builds upon previous work where the underlying structure was a complete graph (i.e. there was effectively no structure). Here, we consider alternative network structures and a wider variety of, mainly larger, populations. Previously, we had found when cooperation could evolve, depending upon the values of a range of population parameters. In our current work, we see that the complete graph considered before promotes stability, with populations of cooperators or defectors being relatively hard to replace. By contrast, the star graph promotes instability, and often neither type of population can resist replacement. We discuss potential reasons for this in terms of network topology.

本研究采用马尔可夫运动模型（Markov movement model），对基于潜在空间结构进行交互的移动种群开展建模。种群间的交互以公共物品博弈（public goods game）的形式展开，且群体规模可任意设定。个体将基于自身的探索策略与当前群体构成，策略性地选择停留在当前位置，或是迁移至邻近位置。本研究基于此前的相关工作拓展而来：此前的研究中，潜在交互结构为完全图（complete graph，即本质上无结构化）；而本次研究则考虑了其他类型的网络结构，并纳入了更多样化、且以大规模种群为主的研究对象。此前的研究发现，合作行为能否演化取决于一系列种群参数的取值。在本次研究中，我们发现此前采用的完全图结构能够提升系统稳定性，合作者或背叛者种群均较难被替代。与之形成对比的是，星型图（star graph）则会加剧系统不稳定性，通常两类种群均无法抵御替代。我们将从网络拓扑（network topology）的角度，探讨导致这一差异的潜在原因。