具有相关低秩结构的随机循环网络动力学

Friedrich Schuessler, A. Dubreuil, F. Mastrogiuseppe, S. Ostojic, O. Barak
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引用次数: 54

摘要

大脑中给定的神经网络参与许多不同的任务。这意味着,当考虑一个特定的任务时,网络的连通性包含一个与任务相关的组件和另一个可以被认为是随机的组件。理解结构化和随机组件之间的相互作用,以及它们对网络动态和功能的影响是一个重要的开放性问题。最近的研究解决了随机连接和结构化连接共存的问题,但认为这两个部分是不相关的。这个约束限制了动态,使随机连接失去了功能。训练网络执行特定任务的算法通常会在结构和随机连接之间产生相关性。在这里,我们研究具有相关结构和随机组件的非线性网络,假设结构具有低秩。我们开发了一个分析框架来确定相关性对关节连通性特征值谱的精确影响。我们发现光谱由大量和多个异常值组成,这些异常值的位置是由我们的理论预测的。利用平均场理论,我们证明了这些异常点直接决定了系统的不动点及其稳定性。综上所述,我们的分析阐明了相关性如何允许结构化和随机连接协同扩展网络可用的计算范围。
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Dynamics of random recurrent networks with correlated low-rank structure
A given neural network in the brain is involved in many different tasks. This implies that, when considering a specific task, the network's connectivity contains a component which is related to the task and another component which can be considered random. Understanding the interplay between the structured and random components, and their effect on network dynamics and functionality is an important open question. Recent studies addressed the co-existence of random and structured connectivity, but considered the two parts to be uncorrelated. This constraint limits the dynamics and leaves the random connectivity non-functional. Algorithms that train networks to perform specific tasks typically generate correlations between structure and random connectivity. Here we study nonlinear networks with correlated structured and random components, assuming the structure to have a low rank. We develop an analytic framework to establish the precise effect of the correlations on the eigenvalue spectrum of the joint connectivity. We find that the spectrum consists of a bulk and multiple outliers, whose location is predicted by our theory. Using mean-field theory, we show that these outliers directly determine both the fixed points of the system and their stability. Taken together, our analysis elucidates how correlations allow structured and random connectivity to synergistically extend the range of computations available to networks.
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