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Main Authors: Li, ZeYu, Zhang, Xinsheng, Zhou, Wang
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.03123
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author Li, ZeYu
Zhang, Xinsheng
Zhou, Wang
author_facet Li, ZeYu
Zhang, Xinsheng
Zhou, Wang
contents Distributed algorithms and theories are called for in this era of big data. Under weaker local signal-to-noise ratios, we improve upon the celebrated one-round distributed principal component analysis (PCA) algorithm designed in the spirit of divide-and-conquer, by introducing a few additional communication rounds of consensus. The proposed shifted subspace iteration algorithm is able to close the local phase transition gap, reduce the asymptotic variance, and also alleviate the potential bias. Our estimation procedure is easy to implement and tuning-free. The resulting estimator is shown to be statistically efficient after an acceptable number of iterations. We also discuss extensions to distributed elliptical PCA for heavy-tailed data. Empirical experiments on synthetic and benchmark datasets demonstrate our method's statistical advantage over the divide-and-conquer approach.
format Preprint
id arxiv_https___arxiv_org_abs_2503_03123
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Few-Round Distributed Principal Component Analysis: Closing the Statistical Efficiency Gap by Consensus
Li, ZeYu
Zhang, Xinsheng
Zhou, Wang
Methodology
Distributed algorithms and theories are called for in this era of big data. Under weaker local signal-to-noise ratios, we improve upon the celebrated one-round distributed principal component analysis (PCA) algorithm designed in the spirit of divide-and-conquer, by introducing a few additional communication rounds of consensus. The proposed shifted subspace iteration algorithm is able to close the local phase transition gap, reduce the asymptotic variance, and also alleviate the potential bias. Our estimation procedure is easy to implement and tuning-free. The resulting estimator is shown to be statistically efficient after an acceptable number of iterations. We also discuss extensions to distributed elliptical PCA for heavy-tailed data. Empirical experiments on synthetic and benchmark datasets demonstrate our method's statistical advantage over the divide-and-conquer approach.
title Few-Round Distributed Principal Component Analysis: Closing the Statistical Efficiency Gap by Consensus
topic Methodology
url https://arxiv.org/abs/2503.03123