English

Quantum advantage for computations with limited space

Quantum Physics 2021-11-19 v2 Emerging Technologies

Abstract

Quantum computations promise the ability to solve problems intractable in the classical setting. Restricting the types of computations considered often allows to establish a provable theoretical advantage by quantum computations, and later demonstrate it experimentally. In this paper, we consider space-restricted computations, where input is a read-only memory and only one (qu)bit can be computed on. We show that nn-bit symmetric Boolean functions can be implemented exactly through the use of quantum signal processing as restricted space quantum computations using O(n2)O(n^2) gates, but some of them may only be evaluated with probability 1/2+O(n/2n)1/2 + O(n/\sqrt{2}^n) by analogously defined classical computations. We experimentally demonstrate computations of 33-, 44-, 55-, and 66-bit symmetric Boolean functions by quantum circuits, leveraging custom two-qubit gates, with algorithmic success probability exceeding the best possible classically. This establishes and experimentally verifies a different kind of quantum advantage -- one where quantum scrap space is more valuable than analogous classical space -- and calls for an in-depth exploration of space-time tradeoffs in quantum circuits.

Keywords

Cite

@article{arxiv.2008.06478,
  title  = {Quantum advantage for computations with limited space},
  author = {Dmitri Maslov and Jin-Sung Kim and Sergey Bravyi and Theodore J. Yoder and Sarah Sheldon},
  journal= {arXiv preprint arXiv:2008.06478},
  year   = {2021}
}

Comments

12 pages, 6 figures; improved theory and experiments

R2 v1 2026-06-23T17:52:01.898Z