谷歌搜索大脑:发现层次和不对称网络结构,在神经科学中的应用

Q3 Mathematics Internet Mathematics Pub Date : 2011-11-28 DOI:10.1080/15427951.2011.604284
J. J. Crofts, D. Higham
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引用次数: 27

摘要

层次组织是自然界和技术中出现的许多有向网络的共同特征。例如,基于管理状态的良好定义的消息传递框架通常存在于业务组织中。然而,在许多现实世界的网络中,这种层级模式不太可能如此透明。由于经验数据被整理的性质,节点通常会被排序,以掩盖任何潜在的结构。此外,即使是少数环节也有可能违反任何整体的“指挥系统”,这使得确定这种结构极具挑战性。在这里,我们解决了如何重新排序有向网络以揭示这种类型的层次结构的问题。在此过程中,我们还研究了在给定特定节点顺序的情况下量化层次结构级别的任务。我们研究了各种各样的方法。利用图拉普拉斯文献中的思想,我们展示了一个相关的离散优化问题导致了一个自然的分层节点排序。我们还表明,这种排名是通过与一个新的依赖范围的分层随机图模型相关的最大似然问题产生的。这种随机图的洞察力使我们能够计算出一个似然比,它量化了给定网络分层的总体趋势。在有向行走组合的基础上,对这种节点排序算法进行了推广。顺便说一下,我们注意到b谷歌的PageRank算法处理了一个密切相关的问题,并且可能是从组合的、行走计数的观点出发的。我们在合成网络数据和神经科学的现实世界网络上演示了结果算法的性能,其中结果可能得到生物学验证。
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Googling the Brain: Discovering Hierarchical and Asymmetric Network Structures, with Applications in Neuroscience
Abstract Hierarchical organization is a common feature of many directed networks arising in nature and technology. For example, a well-defined message-passing framework based on managerial status typically exists in a business organization. However, in many real-world networks, such patterns of hierarchy are unlikely to be quite so transparent. Due to the nature in which empirical data are collated, the nodes will often be ordered so as to obscure any underlying structure. In addition, the possibility of even a small number of links violating any overall “chain of command” makes the determination of such structures extremely challenging. Here we address the issue of how to reorder a directed network to reveal this type of hierarchy. In doing so, we also look at the task of quantifying the level of hierarchy, given a particular node ordering. We look at a variety of approaches. Using ideas from the graph Laplacian literature, we show that a relevant discrete optimization problem leads to a natural hierarchical node ranking. We also show that this ranking arises via a maximum likelihood problem associated with a new range-dependent hierarchical random-graph model. This random-graph insight allows us to compute a likelihood ratio that quantifies the overall tendency for a given network to be hierarchical. We also develop a generalization of this node-ordering algorithm based on the combinatorics of directed walks. In passing, we note that Google's PageRank algorithm tackles a closely related problem, and may also be motivated from a combinatoric, walk-counting viewpoint. We illustrate the performance of the resulting algorithms on synthetic network data, and on a real-world network from neuroscience where results may be validated biologically.
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Internet Mathematics
Internet Mathematics Mathematics-Applied Mathematics
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