Structured Parameterization and Non-Stabilizerness in Hypergraph QAOA
Abstract
The quantum approximate optimization algorithm (QAOA) has emerged as a promising candidate for demonstrating quantum advantage on noisy intermediate-scale quantum (NISQ) devices. While various QAOA parameterization schemes exist, ranging from the original single-angle approach to the more expressive multi-angle quantum approximate optimization algorithm (MA-QAOA) and automorphic-angle quantum approximate optimization algorithm (AA-QAOA), each presents distinct trade-offs between expressiveness and classical optimization complexity. In this work, we introduce the -interaction-angle quantum approximate optimization algorithm (A-QAOA), a parameterization scheme that groups cost function terms by their -body interaction order, providing a natural middle ground between parameter efficiency and solution quality. This approach is particularly well-suited for combinatorial optimization problems defined on hypergraphs, where multi-body interactions naturally arise in applications such as Boolean satisfiability and resource allocation with multi-party constraints. We benchmark A-QAOA against standard single-angle quantum approximate optimization algorithm (SA-QAOA), MA-QAOA, and AA-QAOA on two problem classes: 3-uniform cyclic sign-alternating hypergraphs and random coefficient hypergraphs. Our results demonstrate that A-QAOA achieves approximation ratios comparable to MA-QAOA while requiring significantly fewer function evaluations, thereby reducing quantum resource consumption.
Cite
@article{arxiv.2605.01620,
title = {Structured Parameterization and Non-Stabilizerness in Hypergraph QAOA},
author = {Evan Camilleri and André Xuereb and Tony J. G. Apollaro and Mirko Consiglio},
journal= {arXiv preprint arXiv:2605.01620},
year = {2026}
}
Comments
13 pages, 7 figures