English

Space-Efficient Error Reduction for Unitary Quantum Computations

Quantum Physics 2016-08-29 v1 Computational Complexity

Abstract

This paper develops general space-efficient methods for error reduction for unitary quantum computation. Consider a polynomial-time quantum computation with completeness cc and soundness ss, either with or without a witness (corresponding to QMA and BQP, respectively). To convert this computation into a new computation with error at most 2p2^{-p}, the most space-efficient method known requires extra workspace of O(plog1cs){O \bigl( p \log \frac{1}{c-s} \bigr)} qubits. This space requirement is too large for scenarios like logarithmic-space quantum computations. This paper presents error-reduction methods for unitary quantum computations (i.e., computations without intermediate measurements) that require extra workspace of just O(logpcs){O \bigl( \log \frac{p}{c-s} \bigr)} qubits. This in particular gives the first methods of strong amplification for logarithmic-space unitary quantum computations with two-sided bounded error. This also leads to a number of consequences in complexity theory, such as the uselessness of quantum witnesses in bounded-error logarithmic-space unitary quantum computations, the PSPACE upper bound for QMA with exponentially-small completeness-soundness gap, and strong amplification for matchgate computations.

Keywords

Cite

@article{arxiv.1604.08192,
  title  = {Space-Efficient Error Reduction for Unitary Quantum Computations},
  author = {Bill Fefferman and Hirotada Kobayashi and Cedric Yen-Yu Lin and Tomoyuki Morimae and Harumichi Nishimura},
  journal= {arXiv preprint arXiv:1604.08192},
  year   = {2016}
}

Comments

Accepted to ICALP 2016

R2 v1 2026-06-22T13:42:50.888Z