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Laplace--Fisher Gate Identities for Optimal Matrix-Gated Blended Score Estimation

Published 23 Jun 2026 in math.ST and cs.LG | (2606.25169v1)

Abstract: Sampling from an unnormalized target by reversing an Ornstein--Uhlenbeck diffusion requires the score of each noise-perturbed marginal. Tweedie's identity and a target-score identity give unbiased finite-reference estimators for this score. Scalar blends can reduce variance, but are too rigid for singular or strongly anisotropic targets. We cast blended score estimation as conditional risk minimization over matrix-valued blending coefficients, or gates, and derive the variance-optimal gate [ \Gstar(y,t)=\alphat2\bigl(\alphat2 I_d+\gammat,\E[H_0(X_0)\mid Y_t=y]\bigr){-1},\qquad H_0=-\nabla2\log p_0 . ] Here (\alphat=e{-t}) and (\gammat=1-e{-2t}). We call this formula the \emph{Laplace--Fisher Gate Identity} (\LFGI{}). Since the Tweedie--TSI disagreement has conditional mean zero, the gate changes estimator variance without changing its expected value. We give the Gaussian special case and prove finite-reference consistency and stability bounds for estimating the gate from weighted reference samples. We apply the finite-reference LFGI estimator to normalized density evaluation for Bayesian inverse problems. When MCMC pilot samples and derivative information are available, LFGI uses these byproducts to construct a normalized posterior-density surrogate. The surrogate enables posterior-energy evaluation, model-evidence estimation, and density-based diagnostics beyond those available from samples alone. On a PDE-constrained inverse-problem benchmark, LFGI improves posterior-density calibration and sampling diagnostics relative to the other tested score-estimator classes, and known-evidence experiments check absolute calibration in Gaussian and non-Gaussian settings.

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