Robust high dimensional expectation maximization algorithm via trimmed hard thresholding

Di Wang; Xiangyu Guo; Shi Li; Jinhui Xu

doi:10.1007/s10994-020-05926-z

Robust high dimensional expectation maximization algorithm via trimmed hard thresholding

Department of Computer Science and Engineering

SUNY Buffalo

Research output: Contribution to journal › Article › peer-review

3 Scopus citations

Abstract

In this paper, we study the problem of estimating latent variable models with arbitrarily corrupted samples in high dimensional space (i.e., d≫ n) where the underlying parameter is assumed to be sparse. Specifically, we propose a method called Trimmed (Gradient) Expectation Maximization which adds a trimming gradients step and a hard thresholding step to the Expectation step (E-step) and the Maximization step (M-step), respectively. We show that under some mild assumptions and with an appropriate initialization, the algorithm is corruption-proofing and converges to the (near) optimal statistical rate geometrically when the fraction of the corrupted samples ϵ is bounded by O~(1n). Moreover, we apply our general framework to three canonical models: mixture of Gaussians, mixture of regressions and linear regression with missing covariates. Our theory is supported by thorough numerical results.

Original language	English
Pages (from-to)	2283-2311
Number of pages	29
Journal	Machine Learning
Volume	109
Issue number	12
DOIs	https://doi.org/10.1007/s10994-020-05926-z
State	Published - Dec 2020

Keywords

Expectation maximixation
Gaussian mixture model
High dimensional statistics
Iterative hard thresholding
Robust statistics

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title = "Robust high dimensional expectation maximization algorithm via trimmed hard thresholding",

abstract = "In this paper, we study the problem of estimating latent variable models with arbitrarily corrupted samples in high dimensional space (i.e., d≫ n) where the underlying parameter is assumed to be sparse. Specifically, we propose a method called Trimmed (Gradient) Expectation Maximization which adds a trimming gradients step and a hard thresholding step to the Expectation step (E-step) and the Maximization step (M-step), respectively. We show that under some mild assumptions and with an appropriate initialization, the algorithm is corruption-proofing and converges to the (near) optimal statistical rate geometrically when the fraction of the corrupted samples ϵ is bounded by O\textasciitilde{}(1n). Moreover, we apply our general framework to three canonical models: mixture of Gaussians, mixture of regressions and linear regression with missing covariates. Our theory is supported by thorough numerical results.",

keywords = "Expectation maximixation, Gaussian mixture model, High dimensional statistics, Iterative hard thresholding, Robust statistics",

author = "Di Wang and Xiangyu Guo and Shi Li and Jinhui Xu",

note = "Publisher Copyright: {\textcopyright} 2020, The Author(s), under exclusive licence to Springer Science+Business Media LLC, part of Springer Nature.",

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doi = "10.1007/s10994-020-05926-z",

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T1 - Robust high dimensional expectation maximization algorithm via trimmed hard thresholding

AU - Wang, Di

AU - Guo, Xiangyu

AU - Li, Shi

AU - Xu, Jinhui

PY - 2020/12

Y1 - 2020/12

N2 - In this paper, we study the problem of estimating latent variable models with arbitrarily corrupted samples in high dimensional space (i.e., d≫ n) where the underlying parameter is assumed to be sparse. Specifically, we propose a method called Trimmed (Gradient) Expectation Maximization which adds a trimming gradients step and a hard thresholding step to the Expectation step (E-step) and the Maximization step (M-step), respectively. We show that under some mild assumptions and with an appropriate initialization, the algorithm is corruption-proofing and converges to the (near) optimal statistical rate geometrically when the fraction of the corrupted samples ϵ is bounded by O~(1n). Moreover, we apply our general framework to three canonical models: mixture of Gaussians, mixture of regressions and linear regression with missing covariates. Our theory is supported by thorough numerical results.

AB - In this paper, we study the problem of estimating latent variable models with arbitrarily corrupted samples in high dimensional space (i.e., d≫ n) where the underlying parameter is assumed to be sparse. Specifically, we propose a method called Trimmed (Gradient) Expectation Maximization which adds a trimming gradients step and a hard thresholding step to the Expectation step (E-step) and the Maximization step (M-step), respectively. We show that under some mild assumptions and with an appropriate initialization, the algorithm is corruption-proofing and converges to the (near) optimal statistical rate geometrically when the fraction of the corrupted samples ϵ is bounded by O~(1n). Moreover, we apply our general framework to three canonical models: mixture of Gaussians, mixture of regressions and linear regression with missing covariates. Our theory is supported by thorough numerical results.

KW - Expectation maximixation

KW - Gaussian mixture model

KW - High dimensional statistics

KW - Iterative hard thresholding

KW - Robust statistics

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DO - 10.1007/s10994-020-05926-z

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JO - Machine Learning

JF - Machine Learning

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Robust high dimensional expectation maximization algorithm via trimmed hard thresholding

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