English

Quantum and Classical Communication-Space Tradeoffs from Rectangle Bounds

Quantum Physics 2016-09-08 v1 Computational Complexity

Abstract

We derive lower bounds for tradeoffs between the communication C and space S for communicating circuits. The first such bound applies to quantum circuits. If for any function f with image Z the multicolor discrepancy of the communication matrix of f is 1/2^d, then any bounded error quantum protocol with space S, in which Alice receives some l inputs, Bob r inputs, and they compute f(x_i,y_j) for the lr pairs of inputs (x_i,y_j) needs communication C=\Omega(lrd \log |Z|/S). In particular, n\times n-matrix multiplication over a finite field F requires C=\Theta(n^3\log^2 |F|/S). We then turn to randomized bounded error protocols, and derive the bound C=\Omega(n^3/S^2) for Boolean matrix multiplication, utilizing a new direct product result for the one-sided rectangle lower bound on randomized communication complexity. This implies a separation between quantum and randomized protocols.

Keywords

Cite

@article{arxiv.quant-ph/0412088,
  title  = {Quantum and Classical Communication-Space Tradeoffs from Rectangle Bounds},
  author = {Hartmut Klauck},
  journal= {arXiv preprint arXiv:quant-ph/0412088},
  year   = {2016}
}

Comments

17 pages, appears at FSTTCS '04