Elevating Variational Quantum Semidefinite Programs for Polynomial Objectives
Abstract
Many practically important NP-hard optimization problems are inherently higher-order polynomial optimizations, which are typically addressed using approximation algorithms. Classical relaxations express polynomial objectives over a polynomial basis and solve the resulting quadratic objective as a semidefinite program, which can significantly inflate problem size and degrade approximation behavior. Variational quantum analogues to classical semidefinite programs (vQSDPs) are near-term formulations geared towards quadratic objectives. We introduce Product-State Lifting (PSL), a simple product-register encoding that upgrades any vQSDP with basis-state encoding to tackle -degree polynomial optimization. This upgrade requires only a linear increase in resources with constraints constant in . As a worked example, we pair PSL with the recently-proposed vQSDP with the Hadamard test and approximate amplitude constraints [Quantum 7, 1057 (2023)], and outline an application to Max-SAT. PSL maintains the device-friendly structure of vQSDPs while making polynomial degree a linear resource parameter, offering a general path from quadratic to polynomial optimization without the constraint growth typical of classical relaxations.
Cite
@article{arxiv.2408.07774,
title = {Elevating Variational Quantum Semidefinite Programs for Polynomial Objectives},
author = {Iria W. Wang and Robin Brown and Taylor L. Patti and Anima Anandkumar and Marco Pavone and Susanne F. Yelin},
journal= {arXiv preprint arXiv:2408.07774},
year = {2026}
}
Comments
15 pages, 4 figures