Complete convergence of the Hilbert transform

Abstract

Suppose that \aj\∈ 1, and suppose that for any sequence (tn) of integers there exits a constant C1>0 such that \k∈Z:n≥ 1|Σi∈ Bn-tn \!\!\!1.9ex\; ak+ii|>λ\\\ ≤ C1\k∈Z:n≥ 1|Σi∈ Bn \!\!1.9ex\; ak+ii|>λ\, for all λ >0, where Bn=\-n, -(n-1), -(n-2),… , n-2, n-1, n\. Then there is a constant C2>0 which does not depend on the sequence \aj\ such that Σn=1∞\k∈Z:|Σi=-nn \!\!1.9ex\; ak+ii|>λ\≤C2λΣi=-∞∞|ai| for all λ>0. Let (X,B,μ ) be a measure space, τ :X X an invertible measure-preserving transformation, and suppose that f∈ L1(X) such that for any sequence (tn) of integers there exists a constant C1>0 such that μ\ x: n≥ 1|Σi∈ Bn-tn\!\!\!1.9ex\; f(τix)i| >λ \≤ C1μ\x: n≥ 1|Σi∈ Bn\!\!1.9ex\; f(τi x)i|>λ \ for all λ >0, where Bn=\-n, -(n-1), -(n-2),… , n-2, n-1, n\. Then there exists a constant C2>0 which does not depend on f such that Σn=1∞μ\x:|Σi=-nn\!\!1.9ex \;f(τix)i|>λ\≤C2λ\|f\|1 for all λ >0.