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Quantum Lower Bounds for Approximate Counting via Laurent Polynomials

Quantum Physics 2021-03-18 v3 Computational Complexity

Abstract

We study quantum algorithms that are given access to trusted and untrusted quantum witnesses. We establish strong limitations of such algorithms, via new techniques based on Laurent polynomials (i.e., polynomials with positive and negative integer exponents). Specifically, we resolve the complexity of approximate counting, the problem of multiplicatively estimating the size of a nonempty set S[N]S \subseteq [N], in two natural generalizations of quantum query complexity. Our first result holds in the standard Quantum Merlin--Arthur (QMA\mathsf{QMA}) setting, in which a quantum algorithm receives an untrusted quantum witness. We show that, if the algorithm makes TT quantum queries to SS, and also receives an (untrusted) mm-qubit quantum witness, then either m=Ω(S)m = \Omega(|S|) or T=Ω(N/S)T=\Omega \bigl(\sqrt{N/\left| S\right| } \bigr). This is optimal, matching the straightforward protocols where the witness is either empty, or specifies all the elements of SS. As a corollary, this resolves the open problem of giving an oracle separation between SBP\mathsf{SBP}, the complexity class that captures approximate counting, and QMA\mathsf{QMA}. In our second result, we ask what if, in addition to a membership oracle for SS, a quantum algorithm is also given "QSamples" -- i.e., copies of the state S=1SiSi\left| S\right\rangle = \frac{1}{\sqrt{\left| S\right| }} \sum_{i\in S}|i\rangle -- or even access to a unitary transformation that enables QSampling? We show that, even then, the algorithm needs either Θ(N/S)\Theta \bigl(\sqrt{N/\left| S\right| }\bigr) queries or else Θ(min{S1/3,N/S})\Theta \bigl(\min \bigl\{\left| S\right| ^{1/3}, \sqrt{N/\left| S\right| }\bigr\}\bigr) QSamples or accesses to the unitary. Our lower bounds in both settings make essential use of Laurent polynomials, but in different ways.

Keywords

Cite

@article{arxiv.1904.08914,
  title  = {Quantum Lower Bounds for Approximate Counting via Laurent Polynomials},
  author = {Scott Aaronson and Robin Kothari and William Kretschmer and Justin Thaler},
  journal= {arXiv preprint arXiv:1904.08914},
  year   = {2021}
}

Comments

This paper subsumes preprints arXiv:1808.02420 and arXiv:1902.02398. v1: 43 pages. v2: Results strengthened. v3: Minor revisions and references to followup work. 50 pages, 3 figures. To appear in CCC 2020

R2 v1 2026-06-23T08:44:09.647Z