On the monotonicity of discrete entropy for log-concave random vectors on Zd

Abstract

We prove the following type of discrete entropy monotonicity for sums of isotropic, log-concave, independent and identically distributed random vectors X1,…,Xn+1 on Zd: H(X1+·s+Xn+1) ≥ H(X1+·s+Xn) + d2(n+1n) +o(1), where o(1) vanishes as H(X1) ∞. Moreover, for the o(1)-term, we obtain a rate of convergence O(H(X1)e-1dH(X1)), where the implied constants depend on d and n. This generalizes to Zd the one-dimensional result of the second named author (2023). As in dimension one, our strategy is to establish that the discrete entropy H(X1+·s+Xn) is close to the differential (continuous) entropy h(X1+U1+·s+Xn+Un), where U1,…, Un are independent and identically distributed uniform random vectors on [0,1]d and to apply the theorem of Artstein, Ball, Barthe and Naor (2004) on the monotonicity of differential entropy. In fact, we show this result under more general assumptions than log-concavity, which are preserved up to constants under convolution. In order to show that log-concave distributions satisfy our assumptions in dimension d2, more involved tools from convex geometry are needed because a suitable position is required. We show that, for a log-concave function on Rd in isotropic position, its integral, barycenter and covariance matrix are close to their discrete counterparts. Moreover, in the log-concave case, we weaken the isotropicity assumption to what we call almost isotropicity. One of our technical tools is a discrete analogue to the upper bound on the isotropic constant of a log-concave function, which extends to dimensions d1 a result of Bobkov, Marsiglietti and Melbourne (2022).