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Quantum speedup of classical mixing processes

Quantum Physics 2011-11-09 v2

Abstract

Most approximation algorithms for #P-complete problems (e.g., evaluating the permanent of a matrix or the volume of a polytope) work by reduction to the problem of approximate sampling from a distribution π\pi over a large set §\S. This problem is solved using the {\em Markov chain Monte Carlo} method: a sparse, reversible Markov chain PP on §\S with stationary distribution π\pi is run to near equilibrium. The running time of this random walk algorithm, the so-called {\em mixing time} of PP, is O(δ1log1/π)O(\delta^{-1} \log 1/\pi_*) as shown by Aldous, where δ\delta is the spectral gap of PP and π\pi_* is the minimum value of π\pi. A natural question is whether a speedup of this classical method to O(δ1log1/π)O(\sqrt{\delta^{-1}} \log 1/\pi_*), the diameter of the graph underlying PP, is possible using {\em quantum walks}. We provide evidence for this possibility using quantum walks that {\em decohere} under repeated randomized measurements. We show: (a) decoherent quantum walks always mix, just like their classical counterparts, (b) the mixing time is a robust quantity, essentially invariant under any smooth form of decoherence, and (c) the mixing time of the decoherent quantum walk on a periodic lattice Znd\Z_n^d is O(ndlogd)O(n d \log d), which is indeed O(δ1log1/π)O(\sqrt{\delta^{-1}} \log 1/\pi_*) and is asymptotically no worse than the diameter of Znd\Z_n^d (the obvious lower bound) up to at most a logarithmic factor.

Keywords

Cite

@article{arxiv.quant-ph/0609204,
  title  = {Quantum speedup of classical mixing processes},
  author = {Peter C. Richter},
  journal= {arXiv preprint arXiv:quant-ph/0609204},
  year   = {2011}
}

Comments

13 pages; v2 revised several parts