A homogenization principle for total variation

Abstract

A homogenization principle for total variation We prove an inequality comparing the variational distance between pairs of product probability measures to its homogenized counterpart. If P1,…,Pn,Q1,…,Qn are arbitrary probability measures on a measurable space and P:=1nΣi=1n Pi, Q:=1nΣi=1n Qi , we show that TV\!(i=1n Pi, i=1n Qi) \;\; c\,TV( P n, Q n), where c>0 is a universal constant. The proof is based on a one-dimensional representation of total variation between products. We embed pairs of probability distributions Pi,Qi into positive measures ηi on R. We then define a functional T over measures on R that realizes TV over products via convolution: TV\!(i=1n Pi, i=1n Qi)=T(η1*·s *ηn). Our main analytic discovery is that for the relevant class of positive measures ηi, the convolution inequality T(η1*·s*ηn) c\,T\!(η*n) holds, where η=1nΣi=1n ηi. Finally, a higher-dimensional lifting argument shows that T\!(η*n) TV( P n, Q n). To our knowledge, both the exact representation and the convolution inequality are new.