English

Computing partition functions in the one clean qubit model

Quantum Physics 2021-03-24 v2

Abstract

We present a method to approximate partition functions of quantum systems using mixed-state quantum computation. For positive semi-definite Hamiltonians, our method has expected running-time that is almost linear in (M/(ϵrelZ))2(M/(\epsilon_{\rm rel}\mathcal{Z} ))^2, where MM is the dimension of the quantum system, Z\mathcal{Z} is the partition function, and ϵrel\epsilon_{\rm rel} is the relative precision. It is based on approximations of the exponential operator as linear combinations of certain operators related to block-encoding of Hamiltonians or Hamiltonian evolutions. The trace of each operator is estimated using a standard algorithm in the one clean qubit model. For large values of Z\mathcal{Z}, our method may run faster than exact classical methods, whose complexities are polynomial in MM. We also prove that a version of the partition function estimation problem within additive error is complete for the so-called DQC1 complexity class, suggesting that our method provides a super-polynomial speedup for certain parameter values. To attain a desired relative precision, we develop a classical procedure based on a sequence of approximations within predetermined additive errors that may be of independent interest.

Keywords

Cite

@article{arxiv.1910.11842,
  title  = {Computing partition functions in the one clean qubit model},
  author = {Anirban N. Chowdhury and Rolando D. Somma and Yigit Subasi},
  journal= {arXiv preprint arXiv:1910.11842},
  year   = {2021}
}

Comments

15 pages, 2 figures

R2 v1 2026-06-23T11:55:11.893Z