Breaking the Finite-Sample Barrier in Entropy Coupling

Abstract

Dependence among marginally constrained observations can break a finite-sample barrier. To formalize this phenomenon, we introduce the minimum list entropy coupling H(P\|Q1,…,Qm), the minimum conditional entropy H(X|Y1,…,Ym) over all joint distributions with prescribed discrete marginals X P and Yi Qi. Unlike classical formulations based on independent observations, our model allows Y1,…,Ym to be arbitrarily dependent while keeping each marginal fixed. This enlarged coupling space reveals a sharp dichotomy: independent observations reduce residual uncertainty exponentially, whereas dependent observations can eliminate it exactly after finitely many samples. We characterize this zero-entropy regime through necessary and sufficient conditions and give concrete structural criteria under which it occurs. In particular, under mild support assumptions, zero entropy is achieved with O((1/P)) observations, where P is the minimum nonzero mass of P. We also develop a greedy algorithm with monotone approximation guarantees for computing H(P\|Q1,…,Qm). Finally, we show that the same framework formalizes finite-sample limits in distribution-matching representation learning and randomness extraction, where zero entropy corresponds to exact recovery and exact extraction.