A High-Frequency Uncertainty Principle for the Fourier-Bessel Transform

Abstract

Motivated by problems in control theory concerning decay rates for the damped wave equation wtt(x,t) + γ(x) wt(x,t) + (- + 1)s/2 w(x,t) = 0, we consider an analogue of the classical Paneah-Logvinenko-Sereda theorem for the Fourier Bessel transform. In particular, if E ⊂ R+ is μα-relatively dense (where dμα(x) ≈ x2α+1\, dx) for α > -1/2, and supp Fα(f) ⊂ [R,R+1], then we show \|f\|L2α(R+) \|f\|L2α(E), for all f∈ L2α(R+), where the constants in do not depend on R > 0. Previous results on PLS theorems for the Fourier-Bessel transform by Ghobber and Jaming (2012) provide bounds that depend on R. In contrast, our techniques yield bounds that are independent of R, offering a new perspective on such results. This result is applied to derive decay rates of radial solutions of the damped wave equation.