Optimal exponents for Hardy--Littlewood inequalities for m-linear operators

Abstract

The Hardy--Littlewood inequalities on p spaces provide optimal exponents for some classes of inequalities for bilinear forms on p spaces. In this paper we investigate in detail the exponents involved in Hardy--Littlewood type inequalities and provide several optimal results that were not achieved by the previous approaches. Our first main result asserts that for q1,...,qm>0 and an infinite-dimensional Banach space Y attaining its cotype Y, if equation* 1p1+...+1pm<1 Y, equation* then the following assertions are equivalent: (a) There is a constant Cp1,...,pmY≥ 1 such that equation* ( Σj1=1∞ ( Σj2=1∞ ·s ( Σjm=1∞ A(ej1,...,ejm) qm) qm-1qm·s ) q1q2 ) 1q1≤ Cp1,...,pmY A equation* for all continuous m-linear operators A: p1× ·s × pm→ Y. (b) The exponents q1,...,qm satisfy equation* q1≥ λ m, Yp1,...,pm,q2≥ λ m-1, Yp2,...,pm,...,qm≥ λ 1, Ypm, equation* where, for k=1,...,m, equation* λ m-k+1, Ypk,...,pm:= Y1-( 1 pk+...+1pm) Y. equation* As an application of the above result we generalize to the m-linear setting one of the classical Hardy--Littlewood inequalities for bilinear forms. Our result is sharp in a very strong sense: the constants and exponents are optimal, even if we consider mixed sums.