English

Quantum query complexity of symmetric oracle problems

Computational Complexity 2021-03-10 v3 Quantum Physics

Abstract

We study the query complexity of quantum learning problems in which the oracles form a group GG of unitary matrices. In the simplest case, one wishes to identify the oracle, and we find a description of the optimal success probability of a tt-query quantum algorithm in terms of group characters. As an application, we show that Ω(n)\Omega(n) queries are required to identify a random permutation in SnS_n. More generally, suppose HH is a fixed subgroup of the group GG of oracles, and given access to an oracle sampled uniformly from GG, we want to learn which coset of HH the oracle belongs to. We call this problem coset identification and it generalizes a number of well-known quantum algorithms including the Bernstein-Vazirani problem, the van Dam problem and finite field polynomial interpolation. We provide character-theoretic formulas for the optimal success probability achieved by a tt-query algorithm for this problem. One application involves the Heisenberg group and provides a family of problems depending on nn which require n+1n+1 queries classically and only 11 query quantumly.

Keywords

Cite

@article{arxiv.1812.09428,
  title  = {Quantum query complexity of symmetric oracle problems},
  author = {Daniel Copeland and Jamie Pommersheim},
  journal= {arXiv preprint arXiv:1812.09428},
  year   = {2021}
}

Comments

v2 25 pages, fixed proof of Prop. 5.6, added Section 7 v3 32 pages, added detail to proofs in Sec. 5, also minor revisions and corrections

R2 v1 2026-06-23T06:54:16.487Z