Article

Approximating the cut-norm via Grothendieck's inequality

Authors:

Assaf NaorAuthors Info & Claims

STOC '04: Proceedings of the thirty-sixth annual ACM symposium on Theory of computing

Pages 72 - 80

https://doi.org/10.1145/1007352.1007371

Published: 13 June 2004 Publication History

Abstract

The cut-norm ||A||_C of a real matrix A=(a_ij)_{i∈ R,j∈S} is the maximum, over all I ⊂ R, J ⊂ S of the quantity | Σ_{i ∈ I, j ∈ J} a_ij|. This concept plays a major role in the design of efficient approximation algorithms for dense graph and matrix problems. Here we show that the problem of approximating the cut-norm of a given real matrix is MAX SNP hard, and provide an efficient approximation algorithm. This algorithm finds, for a given matrix A=(a_ij)_{i ∈ R, j ∈ S}, two subsets I ⊂ R and J ⊂ S, such that | Σ_{i ∈ I, j ∈ J} a_ij| ≥ ρ ||A||_C, where ρ > 0 is an absolute constant satisfying $ρ > 0. 56. The algorithm combines semidefinite programming with a rounding technique based on Grothendieck's Inequality. We present three known proofs of Grothendieck's inequality, with the necessary modifications which emphasize their algorithmic aspects. These proofs contain rounding techniques which go beyond the random hyperplane rounding of Goemans and Williamson [12], allowing us to transfer various algorithms for dense graph and matrix problems to the sparse case.

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Index Terms

Approximating the cut-norm via Grothendieck's inequality
1. Mathematics of computing
  1. Mathematical analysis
    1. Mathematical optimization
    2. Numerical analysis
2. Theory of computation
  1. Design and analysis of algorithms
    1. Mathematical optimization

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cover image ACM Conferences

STOC '04: Proceedings of the thirty-sixth annual ACM symposium on Theory of computing

June 2004

660 pages

ISBN:1581138520

DOI:10.1145/1007352

Program Chair:
László Babai
University of Chicago, Chicago, IL

Copyright © 2004 ACM.

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Published: 13 June 2004

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June 13 - 16, 2004

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Shukla AErementchouk MMazumder P(2024)Scalable almost-linear dynamical Ising machinesNatural Computing10.1007/s11047-024-09983-4Online publication date: 9-Apr-2024
https://doi.org/10.1007/s11047-024-09983-4
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