On the existence of optimizers for nonlinear time-frequency concentration problems: the Wigner distribution

Abstract

We prove that, for any measurable phase space subset Ω⊂R2d with 0<|Ω|<∞ and any 1 p < ∞, the nonlinear concentration problem f ∈ L2(Rd)\0\\|Wf\|Lp(Ω)\|f\|L22 admits an optimizer, where Wf is the Wigner distribution of f. The main obstruction is that Wf is covariant (not invariant) under time-frequency shifts, which impedes weak upper semicontinuity, so the effects of constructive interference must be taken into account. We close this compactness gap via concentration compactness for Heisenberg-type dislocations, together with a new asymptotic formula that quantifies the limiting contribution to concentration over Ω from asymptotically separated wave packets. When p=∞ we also identify the sharp constant 2d and show that it is attained. We also discuss some related extensions: For τ-Wigner distributions with τ∈ (0,1) we isolate a chain phenomenon that obstructs the same strategy beyond the Wigner case (τ=1/2), while for the Born-Jordan distribution in d=1 we obtain weak continuity, and thus existence of concentration optimizers for all 1 p<∞ (the p=∞ supremum equals π but is not attained).