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Hauptverfasser: Lerman, Gilad, Zhang, Teng
Format: Preprint
Veröffentlicht: 2024
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2403.18658
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author Lerman, Gilad
Zhang, Teng
author_facet Lerman, Gilad
Zhang, Teng
contents This work analyzes the subspace-constrained Tyler's estimator (STE), a method designed to recover a low-dimensional subspace from a dataset that may be heavily corrupted by outliers. The STE has previously been shown to be competitive for fundamental computer vision problems. We assume a weak inlier-outlier model and allow the inlier fraction to fall below the threshold at which robust subspace recovery becomes computationally hard. We show that, in this setting, if the initialization of STE satisfies a certain condition, then STE-which is computationally efficient-can effectively recover the underlying subspace. Furthermore, we establish approximate recovery guarantees for STE in the presence of noisy inliers. Finally, under the asymptotic generalized haystack model, we demonstrate that STE initialized with Tyler's M-estimator (TME) recovers the subspace even when the inlier fraction is too small for TME to succeed on its own.
format Preprint
id arxiv_https___arxiv_org_abs_2403_18658
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Theoretical Guarantees for the Subspace-Constrained Tyler's Estimator
Lerman, Gilad
Zhang, Teng
Statistics Theory
Machine Learning
This work analyzes the subspace-constrained Tyler's estimator (STE), a method designed to recover a low-dimensional subspace from a dataset that may be heavily corrupted by outliers. The STE has previously been shown to be competitive for fundamental computer vision problems. We assume a weak inlier-outlier model and allow the inlier fraction to fall below the threshold at which robust subspace recovery becomes computationally hard. We show that, in this setting, if the initialization of STE satisfies a certain condition, then STE-which is computationally efficient-can effectively recover the underlying subspace. Furthermore, we establish approximate recovery guarantees for STE in the presence of noisy inliers. Finally, under the asymptotic generalized haystack model, we demonstrate that STE initialized with Tyler's M-estimator (TME) recovers the subspace even when the inlier fraction is too small for TME to succeed on its own.
title Theoretical Guarantees for the Subspace-Constrained Tyler's Estimator
topic Statistics Theory
Machine Learning
url https://arxiv.org/abs/2403.18658