Limitations of Quantum Approximate Optimization in Solving Generic Higher-Order Constraint-Satisfaction Problems
Abstract
The ability of the Quantum Approximate Optimization Algorithm (QAOA) to deliver a quantum advantage on combinatorial optimization problems is still unclear. Recently, a scaling advantage over a classical solver was postulated to exist for random 8-SAT at the satisfiability threshold. At the same time, the viability of quantum error mitigation for deep circuits on near-term devices has been put in doubt. Here, we analyze the QAOA's performance on random Max-XOR as a function of and the clause-to-variable ratio. As a classical benchmark, we use the Mean-Field Approximate Optimization Algorithm (MF-AOA) and find that it performs better than or equal to the QAOA on average. Still, for large and numbers of layers , there may remain a window of opportunity for the QAOA. However, by extrapolating our numerical results, we find that reaching high levels of satisfaction would require extremely large , which must be considered rather difficult both in the variational context and on near-term devices.
Cite
@article{arxiv.2411.19388,
title = {Limitations of Quantum Approximate Optimization in Solving Generic Higher-Order Constraint-Satisfaction Problems},
author = {Thorge Müller and Ajainderpal Singh and Frank K. Wilhelm and Tim Bode},
journal= {arXiv preprint arXiv:2411.19388},
year = {2024}
}