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Iterative Optimization with Partial Convergence Guarantees on Neutral Atom Quantum Computers

Quantum Physics 2026-04-01 v1

Abstract

Neutral atom quantum computers (NAQCs) have emerged as a promising platform for solving the maximum weighted independent set (MWIS) problem. However, analog quantum approaches face two key limitations: constraints of the atomic layout on realizable graph geometries and the absence of performance guarantees. We introduce Lp-Quts, a hybrid quantum-classical framework that integrates an NAQC sampler into a classical cutting-plane algorithm. At each iteration, a relaxed linear program (RLP) bounds the MWIS and induces a reduced graph from which independent sets are sampled using an analog quantum sampler. A novel sample-informed separation problem guides odd-cycle cut selection and accelerates convergence. For t-perfect graphs, Lp-Quts inherits polynomial-time convergence guarantees from the classical theory of cutting planes. We evaluate our approach on instances with up to 300 vertices -- a scale that exceeds the capabilities of current NAQC hardware. In this regime, Lp-Quts reaches solutions within 5--10\% of optimality, outperforming direct analog quantum protocols and greedy baselines under equal sampling budgets. As expected, simulated annealing remains the strongest sample-based solver at this scale. These results demonstrate how quantum samplers can be effectively embedded within classical optimization frameworks to deliver near-optimal solutions with reduced quantum resources while preserving formal guarantees.

Keywords

Cite

@article{arxiv.2603.28933,
  title  = {Iterative Optimization with Partial Convergence Guarantees on Neutral Atom Quantum Computers},
  author = {Cédrick Perron and Yves Bérubé-Lauzière and Victor Drouin-Touchette},
  journal= {arXiv preprint arXiv:2603.28933},
  year   = {2026}
}
R2 v1 2026-07-01T11:44:53.373Z