Sackler Centre for Consciousness Science and School of Informatics, University of Sussex, Brighton BN1 9QJ, UK.
J Neurosci Methods. 2011 Oct 15;201(2):404-19. doi: 10.1016/j.jneumeth.2011.08.010. Epub 2011 Aug 12.
Granger causality (G-causality) is increasingly employed as a method for identifying directed functional connectivity in neural time series data. However, little attention has been paid to the influence of common preprocessing methods such as filtering on G-causality inference. Filtering is often used to remove artifacts from data and/or to isolate frequency bands of interest. Here, we show [following Geweke (1982)] that G-causality for a stationary vector autoregressive (VAR) process is fully invariant under the application of an arbitrary invertible filter; therefore filtering cannot and does not isolate frequency-specific G-causal inferences. We describe and illustrate a simple alternative: integration of frequency domain (spectral) G-causality over the appropriate frequencies ("band limited G-causality"). We then show, using an analytically solvable minimal model, that in practice G-causality inferences often do change after filtering, as a consequence of large increases in empirical model order induced by filtering. Finally, we demonstrate a valid application of filtering in removing a nonstationary ("line noise") component from data. In summary, when applied carefully, filtering can be a useful preprocessing step for removing artifacts and for furnishing or improving stationarity; however filtering is inappropriate for isolating causal influences within specific frequency bands.
格兰杰因果关系(G-causality)越来越多地被用作识别神经时间序列数据中定向功能连接的方法。然而,人们很少关注常见的预处理方法(如滤波)对 G 因果推断的影响。滤波通常用于从数据中去除伪影和/或隔离感兴趣的频带。在这里,我们展示了[遵循 Geweke(1982)],对于平稳的向量自回归(VAR)过程,任意可逆滤波器的应用完全不变量 G 因果关系;因此,滤波不能也不会隔离特定频率的 G 因果推断。我们描述并说明了一种简单的替代方法:在适当的频率上对频域(谱)G 因果关系进行积分(“带限 G 因果关系”)。然后,我们使用可解析求解的最小模型表明,在实践中,滤波后 G 因果推断通常会发生变化,这是滤波引起的经验模型阶数大幅增加的结果。最后,我们展示了滤波在从数据中去除非平稳(“线噪声”)分量方面的有效应用。总之,当谨慎应用时,滤波可以是去除伪影和提供或改善平稳性的有用预处理步骤;然而,滤波不适合在特定频带内隔离因果影响。
