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An analysis of a Monte Carlo algorithm for estimating the permanent

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Abstract

Karmarkar, Karp, Lipton, Lovász, and Luby proposed a Monte Carlo algorithm for approximating the permanent of a non-negativen×n matrix, which is based on an easily computed, unbiased estimator. It is not difficult to construct 0,1-matrices for which the variance of this estimator is very large, so that an exponential number of trials is necessary to obtain a reliable approximation that is within a constant factor of the correct value.

Nevertheless, the same authors conjectured that for a random 0,1-matrix the variance of the estimator is typically small. The conjecture is shown to be true; indeed, for almost every 0,1-matrixA, just O(nw(n)e -2) trials suffice to obtain a reliable approximation to the permanent ofA within a factor 1±ɛ of the correct value. Here ω(n) is any function tending to infinity asn→∞. This result extends to random 0,1-matrices with density at leastn −1/2ω(n).

It is also shown that polynomially many trials suffice to approximate the permanent of any dense 0,1-matrix, i.e., one in which every row- and column-sum is at least (1/2+α)n, for some constant α>0. The degree of the polynomial bounding the number of trials is a function of α, and increases as α→0.

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Authors and Affiliations

  1. Department of Mathematics, Carnegie Mellon University, 15213, Pittsburgh, PA, U.S.A.

    Alan Frieze

  2. Department of Computer Science, University of Edinburgh, The King's Buildings, EH9 3JZ, Edinburgh, UK

    Mark Jerrum

Authors
  1. Alan Frieze
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  2. Mark Jerrum
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Additional information

Supported by NSF grant CCR-9225008.

The work described here was partly carried out while the author was visiting Princeton University as a guest of DIMACS (Center for Discrete Mathematics and Computer Science).

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Frieze, A., Jerrum, M. An analysis of a Monte Carlo algorithm for estimating the permanent. Combinatorica 15, 67–83 (1995). https://doi.org/10.1007/BF01294460

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  • DOI: https://doi.org/10.1007/BF01294460

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