Functional Donoho-Stark-Elad-Bruckstein-Ricaud-Torr\'esani Uncertainty Principle
Abstract
Let (\fj\j=1n, \τj\j=1n) and (\gk\k=1m, \ωk\k=1m) be p-Schauder frames for a finite dimensional Banach space X. Then for every x ∈ X\0\, we show that align (1) \|θf x\|01p\|θg x\|01q ≥ 11≤ j≤ n, 1≤ k≤ m|fj(ωk)| and \|θg x\|01p\|θf x\|01q≥ 11≤ j≤ n, 1≤ k≤ m|gk(τj)|. align where align* θf: X x (fj(x) )j=1n ∈ p([n]); θg: X x (gk(x) )k=1m ∈ p([m]) align* and q is the conjugate index of p. We call Inequality (1) as Functional Donoho-Stark-Elad-Bruckstein-Ricaud-Torr\'esani Uncertainty Principle. Inequality (1) 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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