Incremental constraint projection methods for variational inequalities

Mengdi Wang; Dimitri P. Bertsekas

doi:10.1007/s10107-014-0769-x

Incremental constraint projection methods for variational inequalities

Mengdi Wang, Dimitri P. Bertsekas

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

38 Scopus citations

Abstract

We consider the solution of strongly monotone variational inequalities of the form F(x∗)′(x-x∗)≥0, for all x∈X. We focus on special structures that lend themselves to sampling, such as when X is the intersection of a large number of sets, and/or F is an expected value or is the sum of a large number of component functions. We propose new methods that combine elements of incremental constraint projection and stochastic gradient. These methods are suitable for problems involving large-scale data, as well as problems with certain online or distributed structures. We analyze the convergence and the rate of convergence of these methods with various types of sampling schemes, and we establish a substantial rate of convergence advantage for random sampling over cyclic sampling.

Original language	English (US)
Pages (from-to)	321-363
Number of pages	43
Journal	Mathematical Programming
Volume	150
Issue number	2
DOIs	https://doi.org/10.1007/s10107-014-0769-x
State	Published - May 2015
Externally published	Yes

Keywords

Alternate/cyclic projection
Incremental method
Random projection
Sampling
Stochastic approximation
Stochastic gradient
Variational inequalities

ASJC Scopus subject areas

Software
General Mathematics

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10.1007/s10107-014-0769-x

Cite this

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AB - We consider the solution of strongly monotone variational inequalities of the form F(x∗)′(x-x∗)≥0, for all x∈X. We focus on special structures that lend themselves to sampling, such as when X is the intersection of a large number of sets, and/or F is an expected value or is the sum of a large number of component functions. We propose new methods that combine elements of incremental constraint projection and stochastic gradient. These methods are suitable for problems involving large-scale data, as well as problems with certain online or distributed structures. We analyze the convergence and the rate of convergence of these methods with various types of sampling schemes, and we establish a substantial rate of convergence advantage for random sampling over cyclic sampling.

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KW - Incremental method

KW - Random projection

KW - Sampling

KW - Stochastic approximation

KW - Stochastic gradient

KW - Variational inequalities

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Incremental constraint projection methods for variational inequalities

Abstract

Keywords

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