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基于部分符号转移熵谱与格兰杰因果关系综合方法从多元时间序列推断加权有向关联网络

Inferring Weighted Directed Association Network from Multivariate Time Series with a Synthetic Method of Partial Symbolic Transfer Entropy Spectrum and Granger Causality.

作者信息

Hu Yanzhu, Zhao Huiyang, Ai Xinbo

机构信息

Beijing Key Laboratory of Work Safety Intelligent Monitoring, Beijing University of Posts and Telecommunications, Beijing, 100876, China.

School of Information Engineering, Xuchang University, Xuchang, 461000, China.

出版信息

PLoS One. 2016 Nov 10;11(11):e0166084. doi: 10.1371/journal.pone.0166084. eCollection 2016.

DOI:10.1371/journal.pone.0166084
PMID:27832153
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5104482/
Abstract

Complex network methodology is very useful for complex system explorer. However, the relationships among variables in complex system are usually not clear. Therefore, inferring association networks among variables from their observed data has been a popular research topic. We propose a synthetic method, named small-shuffle partial symbolic transfer entropy spectrum (SSPSTES), for inferring association network from multivariate time series. The method synthesizes surrogate data, partial symbolic transfer entropy (PSTE) and Granger causality. A proper threshold selection is crucial for common correlation identification methods and it is not easy for users. The proposed method can not only identify the strong correlation without selecting a threshold but also has the ability of correlation quantification, direction identification and temporal relation identification. The method can be divided into three layers, i.e. data layer, model layer and network layer. In the model layer, the method identifies all the possible pair-wise correlation. In the network layer, we introduce a filter algorithm to remove the indirect weak correlation and retain strong correlation. Finally, we build a weighted adjacency matrix, the value of each entry representing the correlation level between pair-wise variables, and then get the weighted directed association network. Two numerical simulated data from linear system and nonlinear system are illustrated to show the steps and performance of the proposed approach. The ability of the proposed method is approved by an application finally.

摘要

复杂网络方法对于复杂系统探索非常有用。然而,复杂系统中变量之间的关系通常并不清晰。因此,从观测数据推断变量之间的关联网络一直是一个热门的研究课题。我们提出了一种名为小洗牌部分符号转移熵谱(SSPSTES)的综合方法,用于从多变量时间序列推断关联网络。该方法综合了替代数据、部分符号转移熵(PSTE)和格兰杰因果关系。合适的阈值选择对于常见的相关性识别方法至关重要,而这对用户来说并不容易。所提出的方法不仅可以在不选择阈值的情况下识别强相关性,还具有相关性量化、方向识别和时间关系识别的能力。该方法可分为三层,即数据层、模型层和网络层。在模型层,该方法识别所有可能的成对相关性。在网络层,我们引入一种滤波算法来去除间接弱相关性并保留强相关性。最后,我们构建一个加权邻接矩阵,每个元素的值代表成对变量之间的相关程度,然后得到加权有向关联网络。通过两个来自线性系统和非线性系统的数值模拟数据来说明所提出方法的步骤和性能。最后通过一个应用实例验证了所提出方法的能力。

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