Unbounded Donoho-Stark-Elad-Bruckstein-Ricaud-Torr\'esani Uncertainty Principles

Abstract

Let (, μ), (, ) be measure spaces and p=1 or p=∞. Let (\fα\α∈ , \τα\α∈ ) and (\gβ\β∈ , \ωβ\β∈ ) be unbounded continuous p-Schauder frames for a Banach space X. Then for every x ∈ ( D(θf) (θg))\0\, we show that alignUB (1) μ(supp(θf x))(supp(θg x)) ≥ 1(α ∈ , β ∈ |fα(ωβ)|)(α ∈ , β ∈ |gβ(τα)|), align where align* &θf:D(θf) x θfx ∈ Lp(, μ); θfx: α (θfx) (α):= fα (x) ∈ K,\\ &θg: D(θg) x θgx ∈ Lp(, ); θgx: β (θgx) (β):= gβ (x) ∈ K. align* We call Inequality (1) as Unbounded Donoho-Stark-Elad-Bruckstein-Ricaud-Torr\'esani Uncertainty Principle. Along with recent Functional Continuous Uncertainty Principle [arXiv:2308.00312], Inequality (1) also improves Ricaud-Torr\'esani uncertainty principle [IEEE Trans. Inform. Theory, 2013]. In particular, it improves Elad-Bruckstein uncertainty principle [IEEE Trans. Inform. Theory, 2002] and Donoho-Stark uncertainty principle [SIAM J. Appl. Math., 1989].

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