Entropic and functional forms of the dimensional Brunn--Minkowski inequality in Gauss space
Abstract
Given even strongly log-concave random vectors X0 and X1 in Rn, we show that a natural joint distribution (X0,X1) satisfies, equation e - 1nD ((1-t)X0 + t X1 Z) ≥ (1-t) e - 1nD (X0 Z) + t e - 1nD ( X1 Z), equation where Z is distributed according to the standard Gaussian measure γ on Rn, t ∈ [0,1], and D(· Z) is the Gaussian relative entropy. This extends and provides a different viewpoint on the corresponding geometric inequality proved by Eskenazis and Moschidis, namely that equation γ ( (1-t) K0 + t K1 )1n ≥ (1-t) γ (K0)1n + t γ (K1)1n, equation when K0, K1 ⊂eq Rn are origin-symmetric convex bodies. As an application, using Donsker--Varadhan duality, we obtain Gaussian Borell--Brascamp--Lieb inequalities applicable to even log-concave functions, which serve as functional forms of the Eskenazis--Moschidis inequality.
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