从峰值数据推断网络结构的Ising模型

arXiv: Quantitative Methods Pub Date : 2011-06-09 DOI:10.1201/B14756-31

J. Hertz, Y. Roudi, J. Tyrcha

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引用次数: 24

摘要

既然可以同时记录来自许多神经元的尖峰序列，那么就需要一种方法来解码这些数据，以了解这些神经元所处的网络。解决这个问题的一种方法是调整一个简单模型网络的参数，使其峰值列车尽可能地与数据相似。模型网络中的连接可以让我们了解生成数据的真实神经元是如何连接的，以及它们是如何相互影响的。在这一章中，我们将描述如何对最简单的一种模型:一个伊辛网络做到这一点。我们推导了用于寻找拟合给定数据集的最佳模型连接强度的算法，以及基于平均场理论的更快的近似算法。我们在模型网络和实验数据上测试了这些算法的性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Ising Models for Inferring Network Structure From Spike Data

Now that spike trains from many neurons can be recorded simultaneously, there is a need for methods to decode these data to learn about the networks that these neurons are part of. One approach to this problem is to adjust the parameters of a simple model network to make its spike trains resemble the data as much as possible. The connections in the model network can then give us an idea of how the real neurons that generated the data are connected and how they influence each other. In this chapter we describe how to do this for the simplest kind of model: an Ising network. We derive algorithms for finding the best model connection strengths for fitting a given data set, as well as faster approximate algorithms based on mean field theory. We test the performance of these algorithms on data from model networks and experiments.

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arXiv: Quantitative Methods

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