Permutation inference for the general linear model.

Algorithms; Animals; Brain/physiology; Brain Mapping/methods; Computer Simulation; Data Interpretation, Statistical; Humans; Linear Models; Nerve Net/physiology; Research Design; General linear model; Multiple regression; Permutation inference; Randomise

Abstract :

[en] Permutation methods can provide exact control of false positives and allow the use of non-standard statistics, making only weak assumptions about the data. With the availability of fast and inexpensive computing, their main limitation would be some lack of flexibility to work with arbitrary experimental designs. In this paper we report on results on approximate permutation methods that are more flexible with respect to the experimental design and nuisance variables, and conduct detailed simulations to identify the best method for settings that are typical for imaging research scenarios. We present a generic framework for permutation inference for complex general linear models (GLMS) when the errors are exchangeable and/or have a symmetric distribution, and show that, even in the presence of nuisance effects, these permutation inferences are powerful while providing excellent control of false positives in a wide range of common and relevant imaging research scenarios. We also demonstrate how the inference on GLM parameters, originally intended for independent data, can be used in certain special but useful cases in which independence is violated. Detailed examples of common neuroimaging applications are provided, as well as a complete algorithm - the "randomise" algorithm - for permutation inference with the GLM.

Disciplines :

Physical, chemical, mathematical & earth Sciences: Multidisciplinary, general & others

Author, co-author :

Winkler, Anderson ; Université de Liège - ULiège > Form. doc. sc. bioméd. & pharma.

Ridgway, Gerard R.

Webster, Matthew A.

Smith, Stephen M.

Nichols, Thomas E.

Language :

English

Title :

Permutation inference for the general linear model.

Publication date :

2014

Journal title :

NeuroImage

ISSN :

1053-8119

eISSN :

1095-9572

Publisher :

Elsevier, Amsterdam, Netherlands

Volume :

Pages :

381-97

Peer reviewed :

Peer Reviewed verified by ORBi

Commentary :

Available on ORBi :

since 03 May 2017

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Scopus citations^®

2329

Scopus citations^®
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2273

OpenCitations

2332

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