English

Fast Solutions to Projective Monotone Linear Complementarity Problems

Machine Learning 2013-01-01 v1 Optimization and Control

Abstract

We present a new interior-point potential-reduction algorithm for solving monotone linear complementarity problems (LCPs) that have a particular special structure: their matrix MRn×nM\in{\mathbb R}^{n\times n} can be decomposed as M=ΦU+Π0M=\Phi U + \Pi_0, where the rank of Φ\Phi is k<nk<n, and Π0\Pi_0 denotes Euclidean projection onto the nullspace of Φ\Phi^\top. We call such LCPs projective. Our algorithm solves a monotone projective LCP to relative accuracy ϵ\epsilon in O(nln(1/ϵ))O(\sqrt n \ln(1/\epsilon)) iterations, with each iteration requiring O(nk2)O(nk^2) flops. This complexity compares favorably with interior-point algorithms for general monotone LCPs: these algorithms also require O(nln(1/ϵ))O(\sqrt n \ln(1/\epsilon)) iterations, but each iteration needs to solve an n×nn\times n system of linear equations, a much higher cost than our algorithm when knk\ll n. Our algorithm works even though the solution to a projective LCP is not restricted to lie in any low-rank subspace.

Keywords

Cite

@article{arxiv.1212.6958,
  title  = {Fast Solutions to Projective Monotone Linear Complementarity Problems},
  author = {Geoffrey J. Gordon},
  journal= {arXiv preprint arXiv:1212.6958},
  year   = {2013}
}
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