Quantitative Convergence and Gaussian Fluctuations for Sequential Interacting Diffusions via Incremental Relative Entropy

Abstract

We study a sequential system of interacting diffusions in which particle i interacts only with its predecessors through the empirical measure μti-1, yielding a directed, non-exchangeable mean-field approximation of a McKean--Vlasov diffusion. Under bounded coefficients and a non-degenerate constant diffusion, we prove the sharp decay of incremental path-space relative entropies, Ri(T):=H(P1:i[0,T] P1:i-1[0,T] P[0,T]) \ \ 1i-1, i2, where P1:i[0,T] is the law of the first i particle paths and P[0,T] the McKean--Vlasov path law. Summing the increments yields the global estimate H (P1:N[0,T]\, \, P[0,T] N)\ \ N, together with quantitative decoupling bounds for tail blocks. As a consequence, the empirical measure converges to the McKean--Vlasov equation in negative Sobolev topologies at the canonical N-1/2 scale. We also establish a Gaussian fluctuation limit for the fluctuation measure, where the sequential architecture produces an explicit feedback correction in the limiting linear SPDE. Our proofs rely on a Girsanov representation, a martingale-difference replacement of predecessor empirical measures by average conditional measures, and an upper-envelope argument.