Transferred QAOA Parameters Remember the Penalty Scale: A λ-Resonance Law for Constrained Quantum Optimization

Abstract

Training the variational angles of the Quantum Approximate Optimization Algorithm once on a small instance and reusing them on larger ones, known as parameter transfer, is the standard route past the exact-simulation wall. Existing literature explains its success almost entirely through structural similarity. We identify a new, independent axis that governs transfer whenever constraints are encoded as penalties: the trained angles memorize the penalty weight λ of their training instance. For any scalarized cost function with an integer-valued violation count, we prove that at arbitrary fixed QAOA angles (β,γ) of depth p, the probability mass F(λ) on the feasible subspace is a finite real trigonometric polynomial in λ whose angular frequencies lie on an integer lattice generated by the trained γ's. Three consequences follow immediately: transfer feasibility is a resonance peaked where the deployment penalty matches the training penalty; the resonance width scales as 1/(vmaxΣk|γk|), so low-|γ| angle sets are systematically more transferable; and the curve exhibits revival peaks at spacings 2π/γk. We confirm all three predictions by exact statevector experiments on a 20-qubit multi-user resource-allocation QUBO. The theorem is independent of how the angles were obtained and applies to any integer-penalty QUBO, recasting a widely reported failure mode of penalty-based QAOA as deterministic, predictable phase interference rather than an energetic tuning problem.

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