English

The Computational Complexity of Quantum Determinants

Computational Complexity 2023-02-17 v1 Number Theory Quantum Algebra Representation Theory

Abstract

In this work, we study the computational complexity of quantum determinants, a qq-deformation of matrix permanents: Given a complex number qq on the unit circle in the complex plane and an n×nn\times n matrix XX, the qq-permanent of XX is defined as Perq(X)=σSnq(σ)X1,σ(1)Xn,σ(n),\mathrm{Per}_q(X) = \sum_{\sigma\in S_n} q^{\ell(\sigma)}X_{1,\sigma(1)}\ldots X_{n,\sigma(n)}, where (σ)\ell(\sigma) is the inversion number of permutation σ\sigma in the symmetric group SnS_n on nn elements. The function family generalizes determinant and permanent, which correspond to the cases q=1q=-1 and q=1q=1 respectively. For worst-case hardness, by Liouville's approximation theorem and facts from algebraic number theory, we show that for primitive mm-th root of unity qq for odd prime power m=pkm=p^k, exactly computing qq-permanent is ModpP\mathsf{Mod}_p\mathsf{P}-hard. This implies that an efficient algorithm for computing qq-permanent results in a collapse of the polynomial hierarchy. Next, we show that computing qq-permanent can be achieved using an oracle that approximates to within a polynomial multiplicative error and a membership oracle for a finite set of algebraic integers. From this, an efficient approximation algorithm would also imply a collapse of the polynomial hierarchy. By random self-reducibility, computing qq-permanent remains to be hard for a wide range of distributions satisfying a property called the strong autocorrelation property. Specifically, this is proved via a reduction from 11-permanent to qq-permanent for O(1/n2)O(1/n^2) points zz on the unit circle. Since the family of permanent functions shares common algebraic structure, various techniques developed for the hardness of permanent can be generalized to qq-permanents.

Keywords

Cite

@article{arxiv.2302.08083,
  title  = {The Computational Complexity of Quantum Determinants},
  author = {Shih-Han Hung and En-Jui Kuo},
  journal= {arXiv preprint arXiv:2302.08083},
  year   = {2023}
}
R2 v1 2026-06-28T08:41:27.981Z