Sufficient conditions on quadratic penalties guarantee that every local minimizer of the box-relaxed QUBO is binary and feasible for open-pit mining, knapsack, and TSP.
Mutation-Guided Differentiable Quadratic Combinatorial Optimization
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abstract
Recent studies suggest that gradient-based methods applied to relaxed box-constrained Quadratic Unconstrained Binary Optimization (QUBO) formulations can outperform classical heuristics in some large-scale regimes, often relying on heavy parallelization. However, these methods still underperform heuristics in other settings. In this work, we clarify this apparent discrepancy through a detailed analysis of the relaxed non-convex QUBO local maxima for both the Maximum Independent Set (MIS) and Maximum Cut (MaxCut) problems, and by introducing a new quadratic objective for MaxCut. Motivated by this analysis, we propose a mutation-based differentiable global reset algorithm, combined with local search to escape local maxima. We term our approach mQO, standing for mutation-based Quadratic combinatorial Optimization. The proposed strategy dramatically improves the performance of gradient-based solvers without heavy reliance on GPU parallelized initializations, indicating that stalling, rather than model capacity or compute, is the dominant bottleneck. As a result, on large-scale graphs, mQO achieves superior performance against state-of-the-art heuristics, commercial integer programming solvers, and recent GPU methods.
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cs.DM 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Local Minima in Quadratic-Penalty Relaxations of Binary Linear Programs
Sufficient conditions on quadratic penalties guarantee that every local minimizer of the box-relaxed QUBO is binary and feasible for open-pit mining, knapsack, and TSP.