Pisier's inequality revisited

Abstract

Given a Banach space X, for n∈ N and p∈ (1,∞) we investigate the smallest constant P∈ (0,∞) for which every f1,...,fn:-1,1n X satisfy ∫-1,1n|Σj=1n ∂jfj()|pdμ() ≤ Pp∫-1,1n∫-1,1n\|Σj=1n j fj()\|pdμ() dμ(δ), where μ is the uniform probability measure on the discrete hypercube -1,1n and ∂jj=1n and =Σj=1n∂j are the hypercube partial derivatives and the hypercube Laplacian, respectively. Denoting this constant by Ppn(X), we show that Ppn(X) Σk=1n1k for every Banach space (X,|·|). This extends the classical Pisier inequality, which corresponds to the special case fj=-1∂j f for some f:-1,1n X. We show that n∈ Ppn(X)<∞ if either the dual X* is a UMD+ Banach space, or for some θ∈ (0,1) we have X=[H,Y]θ, where H is a Hilbert space and Y is an arbitrary Banach space. It follows that n∈ Ppn(X)<∞ if X is a Banach lattice of finite cotype.