On the existence and uniqueness of a bounded solution to a linear differential equation with shifts of argument in Banach space (Q2740283)

Let \((B,\|\cdot \|)\) be a complex Banach space. The author studies the existence and uniqueness of a solution \(x(t)\in C^1(\mathbb R \mapsto B)\), \(\|x(t)\|_{\infty }:=\sup_{t\in \mathbb R}\|x(t)\|<\infty,\) to the equationNEWLINE\[NEWLINE\dot x(t)=\sum_{k=-N}^{N}A_kx(t-k)+y(t)NEWLINE\]NEWLINE where \(A_i\) are bounded linear operators in \(B\), \(N\in \mathbb N\), \(y(t)\in C(\mathbb R \mapsto B)\), \(\|y(t)\|_{\infty }<\infty\). He generalizes the well known result of M. G. Krejn (see the book of \textit{Yu. L. Daletskij} and \textit{M. G. Krejn} [Stability of solutions of differential equations in Banach space. Moscow: Nauka (1970; Zbl 0233.34001)]) and proves that the unique bounded solution exists for arbitrary bounded \(y(t)\) iff for any \(\alpha \in \mathbb R\) the number \(i\alpha \) does not belongs to the spectrum of the operator \(\sum_{k=-N}^{N}e^{-ik\alpha }A_k\). An explicit representation of the bounded solution is also obtained.