Daniels Bryan C, Romanczuk Pawel
ASU-SFI Center for Biosocial Complex Systems, Arizona State University, Tempe, AZ, USA.
Institute for Theoretical Biology, Department of Biology, Humboldt Universität zu Berlin, Berlin, Germany.
Theory Biosci. 2021 Nov;140(4):379-390. doi: 10.1007/s12064-020-00335-1. Epub 2021 Feb 26.
Found in varied contexts from neurons to ants to fish, binary decision-making is one of the simplest forms of collective computation. In this process, information collected by individuals about an uncertain environment is accumulated to guide behavior at the aggregate scale. We study binary decision-making dynamics in networks responding to inputs with small signal-to-noise ratios, looking for quantitative measures of collectivity that control performance in this task. We find that decision accuracy is directly correlated with the speed of collective dynamics, which is in turn controlled by three factors: the leading eigenvalue of the network adjacency matrix, the corresponding eigenvector's participation ratio, and distance from the corresponding symmetry-breaking bifurcation. A novel approximation of the maximal attainable timescale near such a bifurcation allows us to predict how decision-making performance scales in large networks based solely on their spectral properties. Specifically, we explore the effects of localization caused by the hierarchical assortative structure of a "rich club" topology. This gives insight into the trade-offs involved in the higher-order structure found in living networks performing collective computations.
从神经元到蚂蚁再到鱼类,在各种不同的情境中都能发现二元决策,它是集体计算最简单的形式之一。在这个过程中,个体收集到的关于不确定环境的信息会被积累起来,以在总体层面上指导行为。我们研究了在对信噪比小的输入做出响应的网络中的二元决策动态,寻找控制此任务性能的集体性定量指标。我们发现决策准确性与集体动态的速度直接相关,而集体动态速度又由三个因素控制:网络邻接矩阵的主导特征值、相应特征向量的参与率以及与相应对称破缺分岔的距离。在这种分岔附近对最大可达到时间尺度的一种新颖近似,使我们能够仅根据大型网络的谱特性来预测其决策性能的尺度。具体而言,我们探讨了由“富俱乐部”拓扑的分层混合结构引起的局部化效应。这为执行集体计算的生物网络中发现的高阶结构所涉及的权衡提供了见解。
