An End-to-End Hybrid Quantum--Classical Sampling Workflow for Discrete Markov Random Fields: A Reproducible Case Study

Abstract

Sampling from discrete Markov random fields (MRFs) is a hard problem. We study amplitude-encoded i.i.d. sampling for small MRFs where 2n target probabilities are precomputed classically. This removes quantum exponential speedup but allows a clean comparison against classical MCMC based on independent circuit samples (τ≈ 1). Across 60 instances spanning five graph families (1k-step burn-in, 3k retained samples), the mean ESS ratios of Quantum to Single-Site Gibbs, Block Gibbs, Tuned-Block, and Parallel Tempering are 16.35, 7.29, 1.82, and 1.79, showing modern classical samplers substantially close this gap. Amortizing O(2n) preprocessing into wall-clock time, exact inverse-CDF sampling yields 17.7M ESS/s versus 488K ESS/s for the quantum sampler (36× mean rate, 153× per-instance), confirming no wall-clock advantage. We characterize MCMC autocorrelation costs and benchmark amplitude-encoded state preparation at n ∈ \8,10,12\. An MPS scaling study (n 40) shows bond dimension χ=32 achieves F=0.7210.059 at n=40. Finally, a matched-budget VQC vs. MPS comparison at n ∈ \8,10,12\ shows VQC fidelities fall far below MPS: (FVQC, FMPS) = (0.31, 0.99), (0.21, 0.96), (0.17, 0.88) at compressions 10.7×, 34.1×, and 113.8×.

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