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Main Authors: Christ, Ryan, Hall, Ira, Steinsaltz, David
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2212.12539
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author Christ, Ryan
Hall, Ira
Steinsaltz, David
author_facet Christ, Ryan
Hall, Ira
Steinsaltz, David
contents While powerful methods have been developed for high-dimensional hypothesis testing assuming orthogonal parameters, current approaches struggle to generalize to the more common non-orthogonal case. We propose Stable Distillation (SD), a simple paradigm for iteratively extracting independent pieces of information from observed data, assuming a parametric model. When applied to hypothesis testing for large regression models, SD orthogonalizes the effect estimates of non-orthogonal predictors by judiciously introducing noise into the observed outcomes vector, yielding mutually independent p-values across predictors. Generic regression and gene-testing simulations show that SD yields a scalable approach for non-orthogonal designs that exceeds or matches the power of existing methods against sparse alternatives. While we only present explicit SD algorithms for hypothesis testing in ordinary least squares and logistic regression, we provide general guidance for deriving and improving the power of SD procedures.
format Preprint
id arxiv_https___arxiv_org_abs_2212_12539
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Stable Distillation and High-Dimensional Hypothesis Testing
Christ, Ryan
Hall, Ira
Steinsaltz, David
Methodology
While powerful methods have been developed for high-dimensional hypothesis testing assuming orthogonal parameters, current approaches struggle to generalize to the more common non-orthogonal case. We propose Stable Distillation (SD), a simple paradigm for iteratively extracting independent pieces of information from observed data, assuming a parametric model. When applied to hypothesis testing for large regression models, SD orthogonalizes the effect estimates of non-orthogonal predictors by judiciously introducing noise into the observed outcomes vector, yielding mutually independent p-values across predictors. Generic regression and gene-testing simulations show that SD yields a scalable approach for non-orthogonal designs that exceeds or matches the power of existing methods against sparse alternatives. While we only present explicit SD algorithms for hypothesis testing in ordinary least squares and logistic regression, we provide general guidance for deriving and improving the power of SD procedures.
title Stable Distillation and High-Dimensional Hypothesis Testing
topic Methodology
url https://arxiv.org/abs/2212.12539