Related papers: Methods for non-variational heuristic quantum optimisation

Methods for non-variational heuristic quantum optimisation

URL: http://arxiv.org/abs/2602.01353v1
Date: Sun, 01 Feb 2026 17:46:57 GMT
Title: Methods for non-variational heuristic quantum optimisation
Authors: Stuart Ferguson, Petros Wallden,
Abstract summary: We introduce a novel class of quantum optimisations that forgo this variational framework in favour of a hybrid quantum-classical approach.<n>These algorithms are expected to exhibit inherent robustness to noise and support parallel execution across both quantum and classical resources.
Score: 0.5586191108738564
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Optimisation plays a central role in a wide range of scientific and industrial applications, and quantum computing has been widely proposed as a means to achieve computational advantages in this domain. To date, research into the design of noise-resilient quantum algorithms has been dominated by variational approaches, while alternatives remain relatively unexplored. In this work, we introduce a novel class of quantum optimisation heuristics that forgo this variational framework in favour of a hybrid quantum-classical approach built upon Markov Chain Monte Carlo (MCMC) techniques. We introduce Quantum-enhanced Simulated Annealing (QeSA) and Quantum-enhanced Parallel Tempering (QePT), before validating these heuristics on hard Sherrington-Kirkpatrick instances and demonstrate their superior scaling over classical benchmarks. These algorithms are expected to exhibit inherent robustness to noise and support parallel execution across both quantum and classical resources with only classical communication required. As such, they offer a scalable and potentially competitive route toward solving large-scale optimisation problems with near-term quantum devices.

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