Abstract
We address the study of well posedness on Lebesgue spaces of sequences for the following fractional semidiscrete model with finite delay (0.1) Δ α u ( n ) = T u ( n ) + β u ( n − τ ) + f ( n ) , n ∈ N , 0 < α ≤ 1 , β ∈ R , τ ∈ N 0 , where T is a bounded linear operator defined on a Banach space X (typically a space of functions like L p ( Ω ) , 1 < p < ∞ ) and Δ α corresponds to the time discretization of the continuous Riemann–Liouville fractional derivative by means of the Poisson distribution. We characterize the existence and uniqueness of solutions in vector-valued Lebesgue spaces of sequences of the model (0.1) in terms of boundedness of the operator-valued symbol ( ( z − 1 ) α z 1 − α I − β z − τ − T ) − 1 , | z | = 1 , z ≠ 1 , whenever 0 < α ≤ 1 and X satisfies a geometrical condition. For this purpose, we use methods from operator-valued Fourier multipliers and resolvent operator families associated to the homogeneous problem. We apply this result to show a practical and computational criterion in the context of Hilbert spaces.
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