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Speeding up Permutation Testing in Neuroimaging

Computation 2015-02-17 v1 Artificial Intelligence Machine Learning

Abstract

Multiple hypothesis testing is a significant problem in nearly all neuroimaging studies. In order to correct for this phenomena, we require a reliable estimate of the Family-Wise Error Rate (FWER). The well known Bonferroni correction method, while simple to implement, is quite conservative, and can substantially under-power a study because it ignores dependencies between test statistics. Permutation testing, on the other hand, is an exact, non-parametric method of estimating the FWER for a given α\alpha-threshold, but for acceptably low thresholds the computational burden can be prohibitive. In this paper, we show that permutation testing in fact amounts to populating the columns of a very large matrix P{\bf P}. By analyzing the spectrum of this matrix, under certain conditions, we see that P{\bf P} has a low-rank plus a low-variance residual decomposition which makes it suitable for highly sub--sampled --- on the order of 0.5%0.5\% --- matrix completion methods. Based on this observation, we propose a novel permutation testing methodology which offers a large speedup, without sacrificing the fidelity of the estimated FWER. Our evaluations on four different neuroimaging datasets show that a computational speedup factor of roughly 50×50\times can be achieved while recovering the FWER distribution up to very high accuracy. Further, we show that the estimated α\alpha-threshold is also recovered faithfully, and is stable.

Keywords

Cite

@article{arxiv.1502.03536,
  title  = {Speeding up Permutation Testing in Neuroimaging},
  author = {Chris Hinrichs and Vamsi K Ithapu and Qinyuan Sun and Sterling C Johnson and Vikas Singh},
  journal= {arXiv preprint arXiv:1502.03536},
  year   = {2015}
}

Comments

NIPS 13

R2 v1 2026-06-22T08:28:09.550Z