Bounds on approximating Max $k$XOR with quantum and classical local algorithms
Abstract
We consider the power of local algorithms for approximately solving Max XOR, a generalization of two constraint satisfaction problems previously studied with classical and quantum algorithms (MaxCut and Max E3LIN2). In Max XOR each constraint is the XOR of exactly variables and a parity bit. On instances with either random signs (parities) or no overlapping clauses and clauses per variable, we calculate the expected satisfying fraction of the depth-1 QAOA from Farhi et al [arXiv:1411.4028] and compare with a generalization of the local threshold algorithm from Hirvonen et al [arXiv:1402.2543]. Notably, the quantum algorithm outperforms the threshold algorithm for . On the other hand, we highlight potential difficulties for the QAOA to achieve computational quantum advantage on this problem. We first compute a tight upper bound on the maximum satisfying fraction of nearly all large random regular Max XOR instances by numerically calculating the ground state energy density of a mean-field -spin glass [arXiv:1606.02365]. The upper bound grows with much faster than the performance of both one-local algorithms. We also identify a new obstruction result for low-depth quantum circuits (including the QAOA) when , generalizing a result of Bravyi et al [arXiv:1910.08980] when . We conjecture that a similar obstruction exists for all .
Keywords
Cite
@article{arxiv.2109.10833,
title = {Bounds on approximating Max $k$XOR with quantum and classical local algorithms},
author = {Kunal Marwaha and Stuart Hadfield},
journal= {arXiv preprint arXiv:2109.10833},
year = {2022}
}
Comments
21+4 pages, 6 figures, code online at https://nbviewer.jupyter.org/github/marwahaha/QuAIL-2021/blob/main/maxkxor.ipynb and https://nbviewer.jupyter.org/github/marwahaha/QuAIL-2021/blob/main/parisi.ipynb