Unbounded Perturbation of Linear Partial Functional Differential Equations via Yosida Distance

Abstract: This paper is concerned with perturbation of evolution equation with delay $u'(t)=Au(t)+Bu_t \ ()$ where $A,B$ are linear operators in a Banach space $\mathbb{X}$ and from $C([-r,0],\mathbb{X})$ to $\mathbb{X}$, respectively; $r>0$ is a given constant. To measure the size of unbounded perturbation we introduce the so-called \textit{Yosida distance} of linear operators $U$ and $V$ in a Banach space $\mathbb{X}$ as $d_Y(U,V):=\limsup_{\mu\to +\infty} | U_\mu-V_\mu|$, where $U_\mu$ and $V_\mu$ are the Yosida approximations of $U$ and $V$, respectively. The obtained results states that if $d_Y(A, A_1)$ and $d_Y(B, B_1)$ are sufficiently small, then the equation $u'(t)=A_1u(t)+B_1u_t \ ()$ also has an exponential dichotomy, if () has it. The proofs are based on estimates of the Yosida distance of the generators of the solution semigroups generated by () and (*) in the phase space $C([-r,0],\mathbb{X})$ whose domains have no relations at all. The obtained results seem to be new.