The Preisach Extremum Stack is a Shannon-Minimal Sufficient Statistic for Rate-Independent Functionals

Abstract

Let R denote the class of all computable, causal functionals that are rate-independent in the classical sense (invariant under monotone time reparametrizations), and let Pin be the Preisach extremum stack of an input sequence u0:n. We prove a characterization theorem establishing that every F in R satisfies Fu = f(Pin) for a computable f, and derive two information-theoretic results. First, under any probability measure on u0:n, the equality I(u0:n; Fu) = I(Pin; Fu) holds for every F in R and is an immediate corollary of the characterization theorem. Second, the main result: Pin is a Shannon-minimal sufficient statistic in the sense that I(u0:n; Pin) <= I(u0:n; S) for every random variable S from which all R-queries are computable. The proof uses the finite indicator family of [Frydrych, 2026] to reconstruct Pin from any sufficient S. As a corollary, online maintenance of Pin suffices for rate-independent estimation: the NNLS estimator of the Preisach measure mu can be assembled from the incremental stack process (Pit)t=0n in O(k * L2) memory per step, where k = |Pit| and L is the grid resolution.