Inequality on the optimal constant of Young's convolution inequality for locally compact groups and their closed subgroups

Abstract

We define the optimal constant Y ( p1 , p2 ; G ) of Young's convolution inequality as align Y ( p1 , p2 ; G ) := \ \| φ1 * ( φ2 1 / p1' ) \|p φ1 , φ2 G C , \; \| φ1 \|p1 = \| φ2 \|p2 = 1 \ align for a locally compact group G and 1 ≤ p1 , p2 , p ≤ ∞ with 1 / p1 + 1 / p2 = 1 + 1 / p. Here p' is the H\"older conjugate of p, \| · \| p is the Lp-norm on a left Haar measure, and G R> 0 is the modular function. The main result of this paper is that Y ( p1 , p2 ; G ) ≤ Y ( p1 , p2 ; H ) for any closed subgroup H ⊂ G. It follows from this inequality that Y ( p1 , p2 ; G ) ≤ Y ( p1 , p2 ; R ) G - r ( G ) for any connected Lie group G such that the center of the semisimple part is a finite group such as connected linear Lie groups and connected solvable Lie groups, where r ( G ) is the dimension of the maximal compact subgroups of G.