The Computational Complexity of Quantum Determinants
Abstract
In this work, we study the computational complexity of quantum determinants, a -deformation of matrix permanents: Given a complex number on the unit circle in the complex plane and an matrix , the -permanent of is defined as where is the inversion number of permutation in the symmetric group on elements. The function family generalizes determinant and permanent, which correspond to the cases and respectively. For worst-case hardness, by Liouville's approximation theorem and facts from algebraic number theory, we show that for primitive -th root of unity for odd prime power , exactly computing -permanent is -hard. This implies that an efficient algorithm for computing -permanent results in a collapse of the polynomial hierarchy. Next, we show that computing -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 -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 -permanent to -permanent for points 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 -permanents.
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}
}