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Quantum Lower Bound for Approximate Counting Via Laurent Polynomials

Quantum Physics 2018-08-08 v1 Computational Complexity

Abstract

We consider the following problem: estimate the size of a nonempty set S[N]S\subseteq\left[ N\right] , given both quantum queries to a membership oracle for SS, and a device that generates equal superpositions S\left\vert S\right\rangle over SS elements. We show that, if S\left\vert S\right\vert is neither too large nor too small, then approximate counting with these resources is still quantumly hard. More precisely, any quantum algorithm needs either Ω(N/S)\Omega\left( \sqrt{N/\left\vert S\right\vert}\right) queries or else Ω(min{S1/4,N/S})\Omega\left( \min\left\{ \left\vert S\right\vert ^{1/4},\sqrt{N/\left\vert S\right\vert }\right\} \right) copies of S\left\vert S\right\rangle . This means that, in the black-box setting, quantum sampling does not imply approximate counting. The proof uses a novel generalization of the polynomial method of Beals et al. to Laurent polynomials, which can have negative exponents.

Keywords

Cite

@article{arxiv.1808.02420,
  title  = {Quantum Lower Bound for Approximate Counting Via Laurent Polynomials},
  author = {Scott Aaronson},
  journal= {arXiv preprint arXiv:1808.02420},
  year   = {2018}
}

Comments

13 pages

R2 v1 2026-06-23T03:26:57.704Z