Radon transforms with small derivatives and distance inequalities for convex bodies
Abstract
Generalizing the slicing inequality for functions on convex bodies from [11], it was proved in [4] that there exists an absolute constant c so that for any n∈ N, any q∈ [0,n-1) which is not an odd integer, any origin-symmetric convex body K of volume one in Rn and any infinitely smooth probability density f on K we have ∈ Sn-1 1(π q/2) R f(, ·)t(q)(0) ( c(q+1)n)q+12. Here R f(,t) is the Radon transform of f, and the fractional derivative of the order q is taken with respect to the variable t∈ R with fixed ∈ Sn-1. In this note we show that there exist an origin-symmetric convex body K of volume 1 in Rn and a continuous probability density g on K so that ∈ Sn-1 1(π q/2) R g(, ·)t(q)(0) ≤ 1 n (c(q+1))q+12. In the case q=0 this was proved in [5,6], and it was used there to obtain a lower estimate for the maximal outer volume ratio distance from an arbitrary origin-symmetric convex body K to the class of intersection bodies. We extend the latter result to the class L-1-qn of bodies in Rn that embed in L-1-q. Namely, for every q∈ [0,n) there exists an origin-symmetric convex body K in Rn so that dovr(K, L-1-qn) c n 12(q+1).
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