\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2008(2008), No. 69, pp. 1--19.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu  (login: ftp)}
\thanks{\copyright 2008 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2008/69\hfil Perturbed evolution equations with infinite delay]
{Perturbed functional and neutral functional evolution
equations with infinite delay in Fr\'echet spaces}

\author[S. Baghli, M. Benchohra\hfil EJDE-2008/69\hfilneg]
{Selma Baghli,  Mouffak Benchohra}  % in alphabetical order

\address{Selma Baghli \newline
Laboratoire de Math\'ematiques,
Universit\'e de Sidi Bel-Abb\`es\\
BP 89, 22000 Sidi Bel-Abb\`es, Alg\'erie}
\email{selma\_baghli@yahoo.fr}

\address{Mouffak Benchohra \newline
Laboratoire de Math\'ematiques,
Universit\'e de Sidi Bel-Abb\`es\\
BP 89, 22000 Sidi Bel-Abb\`es, Alg\'erie}
\email{benchohra@yahoo.com}

\thanks{Submitted April 15, 2008. Published May 13, 2008.}
\subjclass[2000]{34G20, 34K40}
\keywords{Perturbed functional equation; neutral evolution equations; \hfill\break\indent 
mild solution; fixed-point theory; nonlinear alternative; Fr\'echet
spaces; infinite delay}

\begin{abstract}
 This article shows sufficient conditions for the existence
 of mild solutions, on the positive half-line, for two classes
 of first-order functional and neutral functional perturbed
 differential evolution equations with infinite delay.
 Our main tools are: the nonlinear alternative proved by Avramescu
 for the sum of contractions and completely continuous maps
 in Fr\'echet spaces, and the semigroup theory.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{example}[theorem]{Example}
\newtheorem{proposition}[theorem]{Proposition}
\newtheorem{remark}[theorem]{Remark}
\newtheorem{definition}[theorem]{Definition}

\section{Introduction}

 In this paper, we study the existence of mild solutions,
defined on the positive semi-infinite real interval
$J:=[0,+\infty)$, for two classes of first-order perturbed
functional and neutral functional differential evolution equations
with infinite delay in Fr\'echet spaces. Firstly, in Section 3, we
study the following partial perturbed evolution equation with
infinite delay
\begin{gather}\label{e1}
y'(t)=A(t)y(t)+f(t,y_t)+g(t,y_t), \quad\text{a.e. }t\in J, \\
\label{e2}
y_0=\phi\in \mathcal{B},
\end{gather}
where $f,g:J\times\mathcal{B}\to E$ and $\phi\in\mathcal{B}$ are
given functions and $\{A(t)\}_{0\leq t<+\infty}$ is a family of
linear closed (not necessarily bounded) operators from a real Banach
space $(E,|\cdot|)$ into $E$ that generates an evolution system of
operators $\{U(t,s)\}_{(t,s)\in J\times J}$ for $0\leq s\leq
t<+\infty$.

For any continuous function $y$ defined on $(-\infty,+\infty)$ and
any $t\geq 0$, we denote by $y_t$ the element of $\mathcal{B}$
defined by $y_t(\theta)=y(t+\theta)$ for $\theta \in (-\infty,0]$.
Here $y_t(\cdot)$ represents the history of the state from time
$t-r$ up to the present time $t$. We assume that the histories $y_t$
belongs to some abstract \textit{phase space} $\mathcal{B}$, to be
specified later.

In Section 4, we consider the following perturbed neutral
evolution equation with infinite delay
\begin{gather}\label{e3}
\frac{d}{dt}[y(t)-h(t,y_t)]=A(t)y(t)+f(t,y_t)+g(t,y_t), \quad
\text{a.e. } t\in J, \\
\label{e4}
y_0=\phi\in \mathcal{B},
\end{gather}
where  $A(\cdot)$, $f,g$ and $\phi $ are as in
\eqref{e1}--\eqref{e2} and $h:J\times\mathcal{B}\to E$ is a given
function. Finally in Section 5, we give two examples to
demonstrate our results.

Functional and partial functional differential equations
have been used for modelling the evolution of physical, biological
and economic systems in which the response of
the system depends not only on the current state, but
also on the past history of the system.
For more details on this topic, see for example the books of Kolmanovskii
and Myshkis \cite{KoMy}, Hale and Verduyn Lunel \cite{HaVe} and Wu \cite{Wu},
and the references therein.
In the literature devoted to equations
with finite delay, the state space is the space of all continuous
functions on the finite interval $[-r,0]$ for $r>0$, endowed with
the uniform norm topology.
Some results in this case can be found in the books
by Ahmed \cite{Ahm,Ah1}, Heikkila and Lakshmikantham \cite{HeLa},
 and Pazy \cite{Pa} and the references therein.

When the delay is infinite, the notion of the phase space $\mathcal{B}$
plays an important role in the study of both qualitative and
quantitative theory. A usual choice is a seminormed space satisfying
suitable axioms,  introduced by Hale and Kato in
\cite{HaKa}; see also Corduneanu and Lakshmikantham \cite{CoLa},
Kappel and Schappacher \cite{KaSc} and Schumacher \cite{Sch}. For
a detailed discussion and applications on this topic, we refer the
reader to the book by Hale and Verduyn Lunel \cite{HaVe},
Hino {\em et al.} \cite{HiMuNa} and Wu \cite{Wu}.

Many publications are developed for study of \eqref{e1} with
$A(t)=A$. We refer the reader to the books by  \cite{HeLa} and the
pioneer Hino and Murakami paper \cite{HiMu} and the papers by Adimy
{\em et al } \cite{AdBoEz1,AdBoEz2,AdBoEz3}, Balachandran {\em et
al.} \cite{BaAn,BaLe}, Benchohra and Gorniewicz \cite{BeGo},
Benchohra {\em et al} \cite{BeGoNt, BeNt1}, Ezzinbi \cite{Ez},
Henriquez \cite{Hen} and Hernandez \cite{Her1,Her2},  where
existence and uniqueness, among other things, are derived. In a
series of papers, Belmekki {\em et al} \cite{BeBeEzNt, BeBeNt1,
BeBeNt2, BeBeNt3} considered some classes of semilinear perturbed
functional differential problems where existence of solutions are
given over a bounded interval $[0,b]$.

When $A$ depends on  time, Arara {\em et al} \cite{ArBeGoOu}
considered a control multivalued problem on the bounded interval
$[0,b]$. Recently, Baghli and Benchohra \cite{BaBe1,BaBe2} provided
uniqueness results for some classes of partial and neutral
functional differential evolution equations on the semiinfinite
interval $J=[0,+\infty)$ with local and nonlocal conditions when the
delay is finite. Our main purpose in this paper is to extend some
results from finite delay and those considered on a bounded interval
to partial and neutral \textit{perturbed} evolution equations.

Sufficient conditions are established to obtain the existence of
mild solutions, which are fixed points of the
appropriate operators. We apply a recent nonlinear alternative given
by Avramescu in \cite{Av}, combined with the semigroup theory
\cite{Ahm, Pa}.


\section{Preliminaries}

In this section, we introduce notation, definitions and theorems
to be used later.
Let $C([0,\infty);E)$ be the space of continuous functions from
$[0,\infty)$ to $E$ and $B(E)$ be the space of all bounded linear
operators from $E$ to $E$, with the norm
$$
\| N\|_{B(E)}=\sup  \{ |N(y)| : |y|=1 \}.
$$

A measurable function $y:[0,+\infty)\to E$ is Bochner integrable if
 $|y|$ is Lebesgue integrable. (For details on the Bochner integral
properties, see Yosida \cite{Yo}).

Let $L^{1}([0,+\infty),E)$ be the Banach space of measurable
functions $y:[0,+\infty)\to E$ which are Bochner integrable, equipped with
the norm
$$
\| y\|_{L^{1}}=\int_{0}^{+\infty }|y(t)|\,dt.
$$

Consider the  space
$$
B_{+\infty}=\{y:(-\infty,+\infty)\to E:y|_J\in C(J,E),\; y_0\in
\mathcal{B}\},
$$
where $y|_J$ is the restriction of $y$ to $J$.

In this paper, we will employ the axiomatic definition of the phase
space $\mathcal{B}$ introduced by Hale and Kato in \cite{HaKa} and
follow the terminology used in \cite{HiMuNa}. Thus,
$(\mathcal{B},\|\cdot\|_{\mathcal{B}})$ will be a seminormed linear space of
functions mapping $(-\infty, 0]$ to $E$, and satisfying the
following axioms:
\begin{itemize}

\item[(A1)] If $y: (-\infty, b)\to E$ with $b>0$, is continuous on $[0,b]$
and $ y_0\in \mathcal{B}$, then for every $t\in [0,b)$ the following
conditions hold:\\
(i) $y_t \in \mathcal{B}$;\\
(ii) There exists a positive constant $H$ such that $|y(t)|\leq H\|y_t\|_{\mathcal{B}}$ ;\\
(iii) There exist two functions $K(\cdot),M(\cdot): \mathbb{R}_+\to\mathbb{R}_+$ independent of $y(t)$ with $K$ continuous and $M$
locally bounded such that
$$
\|y_t\|_{\mathcal{B}} \leq K(t)\sup\{ |y(s)|:0\leq s\leq
t\}+M(t)\|y_0\|_{\mathcal{B}}.
$$
Denote $K_b=\sup\{K(t):t\in [0,b]\}$ and
$M_b=\sup\{M(t):t\in [0,b]\}$.

\item[(A2)] For the function $y(.)$ in (A1), $y_t$  is a
$\mathcal{B}$-valued continuous function on $[0,b]$.

\item[(A3)] The space $\mathcal{B}$ is complete.
\end{itemize}

\begin{remark}  \label{rmk2.1} \rm \quad
\begin{itemize}
\item Condition (ii) in (A1) is equivalent to $|\phi(0)|\leq H\|\phi\|_{\mathcal{B}}$ for every
$\phi\in \mathcal{B}$.
\item Since $\|\cdot\|_{\mathcal{B}}$ is a seminorm, two elements
$\phi, \psi \in \mathcal{B}$ can verify $\|\phi-\psi\|_{\mathcal{B}}=0$
without necessarily $\phi(\theta)=\psi(\theta)$ for all $\theta\leq 0$.
\item From the equivalence of (ii), we can see that for all
$\phi, \psi \in \mathcal{B}$ such that
$\|\phi-\psi\|_{\mathcal{B}}=0$. This implies
necessarily that $\phi(0)=\psi(0)$.
\end{itemize}
\end{remark}

Next we present some examples of phase spaces. For more details we
refer to the book by Hino {\em et al} \cite{HiMuNa}.

\begin{example} \label{exa2.2} \rm
Let $BC$ be the space of bounded continuous functions defined from
$(-\infty,0]$ to $E$. Let $BUC$ the space of bounded uniformly
continuous functions defined from $(-\infty,0]$ to $E$. Let
\begin{gather*}
C^{\infty}:=\{\phi\in BC: \lim_{\theta\to-\infty}\phi(\theta)
\text{ exist in }  E\}. \\
C^{0}:=\{\phi\in BC: \lim_{\theta\to-\infty}\phi(\theta)=0\}\,.
\end{gather*}
The space $C^0$ is endowed with the uniform norm
$\|\phi\|=\sup\{|\phi(\theta)|:\theta\leq 0\}$.

Then the spaces $BUC$, $C^{\infty}$ and $C^{0}$ satisfy conditions
(A1)--(A3). $BC$ satisfies (A1),  (A3) but not (A2).
\end{example}

\begin{example} \label{exa2.3} \rm
Let $g$ be a positive continuous function on $(-\infty, 0]$. We
define:
\begin{gather*}
C_{g}:=\{\phi\in C((-\infty,0],E): \frac{\phi(\theta)}{g(\theta)}
  \text{is bounded on}  (-\infty,0]\},\\
C_{g}^{0}:=\{\phi\in
C_{g}:\lim_{\theta\to-\infty}\frac{\phi(\theta)}{g(\theta)}=0\}
\end{gather*}
endowed with the uniform norm
$\|\phi\|=\sup\{\frac{|\phi(\theta)|}{g(\theta)}: \theta\leq 0\}$.

Also we assume that
\begin{itemize}
\item[(G1)] For all $a>0$, $\sup_{0\leq t\leq
a}\sup\{\frac{g(t+\theta)}{g(\theta)}: -\infty<\theta\leq
-t\}<\infty$.
\end{itemize}
Then the spaces $C_{g}$ and $C_{g}^{0}$ satisfy condition (A3). They
satisfy conditions (A1) and (A2) if (G1) holds.
\end{example}

\begin{example} \label{exa2.4} \rm
For each constant $\gamma$, we define the space
$$
C_{\gamma}:=\{\phi\in C((-\infty,0],E):
\lim_{\theta\to-\infty}e^{\gamma\theta}\phi(\theta)
 \text{ exist in }  E\}
$$
endowed with the  norm
$\|\phi\|=\sup\{e^{\gamma\theta}|\phi(\theta)|:  \theta\leq 0\}$.
Then in the space $C_{\gamma}$,  assumptions (A1)--(A3) are
satisfied.
\end{example}

\begin{definition} \label{def2.5} \rm
A function $ f:J\times \mathcal{B}\to E$ is said to be an
$L^{1}$-Carath\'eodory function if it satisfies:
\begin{itemize}
\item[(i)] for each $t\in J$ the function
$f(t,.):\mathcal{B}\to E$ is continuous;

\item[(ii)] for each $y\in \mathcal{B}$ the function
$f(.,y):J\to E$ is measurable;

\item[(iii)] for every positive integer $k$ there
exists $ h_{k}\in L^{1}(J;\mathbb{R}^{+})$ such that
$|f(t,y)|\leq h_{k}(t)$ for  all $\|y\|_{\mathcal{B}}\leq k$
and  almost all  $t\in J$.
\end{itemize}
\end{definition}

 In what follows, we assume that $\{A(t)$, $t \geq 0\}$ is a
family of closed densely defined linear unbounded operators on the
Banach space $E$ and with domain $D(A(t))$ independent of $t$.

\begin{definition} \label{def2.6} \rm
A family of bounded linear operators
$\{U(t,s)\}_{(t,s)\in\Delta}: U(t,s): E\to E$ for $(t,s)\in \Delta
:=\{(t,s)\in J\times J:0\leq s\leq t<+\infty\}$ is called an
evolution system if the following properties are satisfied :
\begin{enumerate}
\item $U(t,t)=I$ where $I$ is the identity operator in
$E$,

\item $U(t,s) U(s,\tau )=U(t,\tau )$ for $0\leq \tau
\leq s\leq t<+\infty$,

\item $U(t,s)\in B(E)$ the space of bounded linear
operators on $E$, where for every $(t,s)\in \Delta $ and for each
$y\in E$, the mapping $(t,s)\to U(t,s) y$ is continuous.

\item $U(t,s)$ is a compact operator for $0<s<t<+\infty$.
\end{enumerate}
\end{definition}

 More details on evolution systems and their properties can be found
in the books by Ahmed \cite {Ahm},
Engel and Nagel \cite {EnNa}, and Pazy \cite {Pa}.

Let $X$ be a Fr\'echet space with a family of semi-norms $\{ \|
\cdot \|_n\} _{n\in \mathbb{N}}$. Let $Y\subset X $, we say that $F$
is bounded if for every $n\in \mathbb{N}$, there exists $ \overline
M_n>0 $ such that
$$
\| y\|_n\leq \overline M_n\quad  \text{for all }y\in Y.
$$
With $X$, we associate a sequence of Banach spaces $\{ (X^{n},\|
\cdot \|_n)\} $ as follows: For every $n\in \mathbb{N}$, we consider
the equivalence relation $x\sim_ny$ if and only if $\| x-y\|_n=0$
for all $x,y\in X$. We denote $X^{n}=(X|_{\sim_n},\| \cdot \|_n)$
the quotient space, the completion of $X^{n}$ with respect to $\|
\cdot \|_n$. To every $Y\subset X$, we associate a sequence the $\{
Y^{n}\} $ of subsets $Y^{n}\subset X^{n}$ as follows : For every
$x\in X$, we denote $[x]_n$ the equivalence class of $x$ of subset
$X^{n}$ and we defined $Y^{n}=\{ [x]_n:x\in Y\} $. We denote
$\overline{Y^{n}}$, $int_n(Y^{n})$ and $\partial_nY^{n}$,
respectively, the closure, the interior and the boundary of $Y^{n}$
with respect to $\| \cdot \|$ in $X^{n}$. We assume that the family
of semi-norms $\{ \| \cdot \|_n\}$ verifies:
$$
\| x\| _{1}\leq \| x\| _{2}\leq \| x\| _{3}\leq ...\quad
\text{for every } x\in X.
$$

\begin{definition}[\cite{Av}] \label{def2.7} \rm
A function $f:X\to X$ is said to be a contraction if for each
$n\in \mathbb{N}$ there exists $k_n\in (0,1)$ such that:
$$
\| f(x)-f(y)\|_n\leq k_n \| x-y\|_n\quad\text{for all }
 x,y\in X.
 $$
\end{definition}

We use the following nonlinear alternative, due to Avramescu,
has been has a version on Banach spaces by Burton-Kirk
\cite{Bu,BuKi}.

\begin{theorem}[Avramescu Nonlinear Alternative  \cite{Av}] \label{th1}
 Let $X$ be a Fr\'echet space and let $A,B:X\to X$ be two operators
satisfying:
\begin{itemize}
\item[(1)] $A$ is a compact operator,

\item[(2)] $B$ is a contraction.
\end{itemize}
Then either one of the following statements holds:
\begin{itemize}
\item[(S1)] The operator $A+B$ has a
 fixed point;

\item[(S2)] The set
$\{x\in X, x=\lambda A(x)+\lambda B(\frac{x}{\lambda})\}$ is
unbounded for $\lambda\in(0,1)$.
\end{itemize}
\end{theorem}


\section{Perturbed Evolution Equations}

Before stating and proving the main result, we give the definition
of mild solution of the semilinear perturbed evolution
\eqref{e1}--\eqref{e2}.

\begin{definition} \label{def3.1} \rm
We say that the function $y(\cdot ):\mathbb{R} \to E$ is a mild
solution of \eqref{e1}--\eqref{e2} if $ y(t)=\phi (t)$ for all
$t\in(-\infty,0]$ and $y$ satisfies the  integral equation
\begin{equation}\label{mild}
y(t)=U(t,0) \phi (0)+\int_{0}^{t}U(t,s) [f(s,y_{s})+g(s,y_s)]\,ds
\quad\text{for each } t\in[0,+\infty).
\end{equation}
\end{definition}

We introduce the following hypotheses:
\begin{itemize}
\item[(H1)] $U(t,s)$ is compact for $t-s>0$ and there exists a constant
$\widehat{M}\geq 1$ such that
$$
\| U(t,s)\|_{B(E)}\leq \widehat{M}\quad \text{for every } (t,s)\in
\Delta.
$$
\item[(H2)] There exists a function $p\in L_{\rm loc}^{1}(J;\mathbb{R}_+)$
and a continuous nondecreasing
function $\psi :\mathbb{R}_+\to (0,\infty)$ and such that:
$$
|f(t,u)|\leq p(t) \psi (\| u\|_{\mathcal{B}}) \quad \text{ for a.e. }
 t\in J \text{ and each }  u\in \mathcal{B}.
 $$
\item[(H3)] There exists a function $\eta\in L_{\rm loc}^1(J,\mathbb{R}_{+})$ such that:
$$
|g(t,u)-g(t,v)|\leq \eta(t)\|u-v\|_{\mathcal{B}} \quad
 \text{for a.e. }  t\in J  \text{ and all }  u,v\in \mathcal{B}.
$$
\end{itemize}

\begin{theorem}\label{th2}
Suppose that hypotheses {\rm (H1)--(H3)} are satisfied and
\begin{equation}\label{cond1}
\int_{\alpha_n}^{+\infty }\frac{ds}{s+\psi (s)}>K_n
\widehat{M}\int_{0}^{n}\max(p(s),\eta(s))ds\,ds\quad \text{for each }
 n\in\mathbb{N}
\end{equation}
with
$$
\alpha_n=K_n\widehat{M}\int_{0}^{n}|g(s,0)|ds
+(K_n\widehat{M}H+M_n)\|\phi\|_{\mathcal{B}}.
$$
Then  \eqref{e1}--\eqref{e2} has a mild
solution.
\end{theorem}

\begin{proof}
 Let us fix $\tau >1$. For every $n\in \mathbb{N}$, we define in
$B_{+\infty}$ the semi-norms
$$
\| y\|_n:=\sup \{  e^{-\tau  L_n^{\ast
}(t)} |y(t)|: t\in [0,n]\}
$$
 where  $L_n^{\ast }(t)=\int_{0}^{t}\overline{l}_n(s)\,ds$
 and $\overline{l}_n(t)=\widehat{M}K_n\eta(t)$. Then $C(B_{+\infty};E)$
is a Fr\'echet space with the family of semi-norms
$\|\cdot\|_{n\in\mathbb{N}}$.

We transform  \eqref{e1}--\eqref{e2} into a fixed-point problem.
Consider the operator $N:B_{+\infty}\to B_{+\infty}$ defined by
\begin{equation}
N(y)(t)=\begin{cases}
\phi(t),&  \text{if }t\in (-\infty,0]; \\
 U(t,0) \phi (0)+\int_{0}^{t}U(t,s) f(s,y_{s})\,ds\\
+\int_{0}^{t}U(t,s) g(s,y_s)\,ds,
 &\text{if }t\in J.
\end{cases}
\end{equation}
Clearly, the fixed points of the operator $N$ are mild solutions of
\eqref{e1}--\eqref{e2}.

 For $\phi \in \mathcal{B}$, we  define the function
$x(.):\mathbb{R}\to E$ by
\[
x(t)=\begin{cases}\phi(t), &\text{if } t\in (-\infty,0];\\
 U(t,0) \phi(0),&\text{if } t\in J.
\end{cases}
\]
Then $x_{0}=\phi$. For each function $z\in B_{+\infty}$, set
\begin{equation}
y(t)=z(t)+x(t).
\end{equation}
It is obvious that $y$ satisfies \eqref{mild} if and only if $z$
satisfies $z_0=0$ and
$$
z(t)=\int_{0}^{t} U(t,s) f(s,z_s+x_s)\,ds+\int_{0}^{t} U(t,s)
 g(s,z_s+x_s)\,ds\quad \text{for } t\in J.
 $$
Let
$B_{+\infty}^0=\{z\in B_{+\infty}:z_0=0\}$.
Define the operators $F,G:B_{+\infty}^0\to B_{+\infty}^0$ by
\begin{gather}
F(z)(t)=\int_{0}^{t} U(t,s) f(s,z_s+x_s)\,ds\quad \text{for }
t\in J, \\
G(z)(t)=\int_{0}^{t} U(t,s) g(s,z_s+x_s)\,ds\quad \text{for }
t\in J.
\end{gather}
Obviously the operator $N$ having a fixed point is equivalent to
$F+G$ having a fixed point. That $F+G$ has a fixed point will be
proved in several steps. First we show that $F$ is continuous and
compact.

\noindent {\bf Step 1:} $F$ is continuous. Let $(z_k)_{k\in
\mathbb{N}}$ be a sequence in $B^0_{+\infty}$ such that $z_k\to z$
in $B^0_{+\infty}$. Then
\begin{align*}
|F(z_k)(t)-F(z)(t)| &= \Big|\int_{0}^{t} U(t,s)
[f(s,z_{k_{s}}+x_s)-f(s,z_s+x_s)]\,ds\Big|\\
&\leq \int_{0}^{t}\|U(t,s)\|_{B(E)}
|f(s,z_{k_{s}}+x_s)-f(s,z_s+x_s)|\,ds\\
&\leq \widehat{M}\int_{0}^{t}|f(s,z_{k_{s}}+x_s)-f(s,z_s+x_s)|\,ds
\to0 \quad\text{as } k\to+\infty.
\end{align*}
Thus $F$ is continuous.

\noindent{\bf Step 2:} $F$ maps bounded sets of $B_{+\infty}^0$ into
bounded sets. For any $d>0$, there exists a positive constant $\ell$
such that for each $z\in B_d=\{z\in B^0_{+\infty}:\|z\|_n\leq d\}$
one has $\|F(z)\|_n\leq\ell$.

Let $z\in B_d$. By the hypotheses (H1) and (H2), we have for each
$t\in J$
\begin{align*}
|F(z)(t)|&= \big|\int_{0}^{t} U(t,s) f(s,z_s+x_s)\,ds\big|\\
&\leq \int_{0}^{t}\|U(t,s)\|_{B(E)} |f(s,z_s+x_s)|\,ds\\
&\leq \widehat{M} \int_{0}^{t}p(s) \psi(\|z_s+x_s)\|_{\mathcal{B}})\,ds.
\end{align*}
Using the assumption (A1), we get
\begin{align*}
\|z_s+x_s\|_{\mathcal{B}}&\leq \|z_s\|_{\mathcal{B}}+\|x_s\|_{\mathcal{B}}\\
&\leq  K(s)|z(s)|+M(s)\|z_0\|_{\mathcal{B}}+
K(s)|x(s)|+M(s)\|x_0\|_{\mathcal{B}}\\
&\leq  K_n|z(s)|+K_n\|U(s,0)\|_{B(E)} |\phi(0)|+M_n\|\phi\|_{\mathcal{B}}\\
&\leq  K_n|z(s)|+K_n\widehat{M}|\phi(0)|+M_n\|\phi\|_{\mathcal{B}}\\
&\leq  K_n|z(s)|+K_n\widehat{M}H\|\phi\|_{\mathcal{B}}+M_n\|\phi\|_{\mathcal{B}}\\
&\leq  K_n|z(s)|+(K_n\widehat{M}H+M_n)\|\phi\|_{\mathcal{B}}.
\end{align*}
Set
$$
c_n:=(K_n\widehat{M}H+M_n)\|\phi\|_{\mathcal{B}},\quad
D_n:=K_nd+c_n.
$$
Then
\begin{equation}\label{zsxs}
\|z_s+x_s\|_{\mathcal{B}}\leq K_n|z(s)|+c_n\leq D_n.
\end{equation}
Using the nondecreasing character of $\psi$, we get
$$|F(z)(t)|\leq\widehat{M} \psi(D_n) \int_{0}^{t}p(s)\,ds.
$$
Thus
$$
\|F(z)\|_{+\infty}\leq \widehat{M} \psi(D_n) \|p\|_{L^1}:=\ell.
$$

\noindent{\bf Step 3:}  $F$ maps bounded sets into equicontinuous sets
of $B^0_{+\infty}$. We consider $B_d$ as in Step 2 and we show
that $F(B_d)$ is
equicontinuous.
Let $\tau_1,\tau_2\in J$ with $\tau_2>\tau_1$ and $z\in
B_d$. Then
\begin{align*}
|F(z)(\tau_2)-F(z)(\tau_1)|
&\leq \Big|\int_{0}^{\tau_1}[U(\tau_2,s)-U(\tau_1,s)]
 f(s,z_s+x_s)\,ds\Big|\\
&\quad+ \Big|\int_{\tau_1}^{\tau_2}U(\tau_2,s) |f(s,z_s+x_s)|\,ds\Big|\\
&\leq \int_{0}^{\tau_1}\|U(\tau_2,s)-U(\tau_1,s)\|_{B(E)} |f(s,z_s+x_s)|\,ds\\
&\quad+ \int_{\tau_1}^{\tau_2}\|U(\tau_2,s)\|_{B(E)} |f(s,z_s+x_s)|\,ds.
\end{align*}
Using $\| z_{s}+x_{s}\|_{\mathcal{B}}\leq D_n$ in \eqref{zsxs} and
the nondecreasing character of $\psi$, we get
\begin{align*}
&|F(z)(\tau_2)-F(z)(\tau_1)|\\
&\leq \psi(D_n)\int_{0}^{\tau_1}\|U(\tau_2,s)-U(\tau_1,s)\|_{B(E)}p(s)ds
 + \widehat{M}\psi(D_n)\int_{\tau_1}^{\tau_2}p(s)ds.
\end{align*}
 The right-hand of the above inequality tends to zero as
$\tau_2-\tau_1\to0$, since $U(t,s)$ is a strongly continuous
operator and the compactness of $U(t,s)$ for $t>s$ implies the
continuity in the uniform operator topology (see \cite{Ah1, Pa}). As
a consequence of Steps 1 to 3 together with the Arzel\'{a}-Ascoli
theorem it suffices to show that the operator $F$ maps $B_d$ into a
precompact set in $E$.

Let $t\in J$ be fixed and let $\epsilon$ be a real number satisfying
$0<\epsilon<t$. For $z\in B_d$ we define
$$F_{\epsilon}(z)(t)=U(t,t-\epsilon)\int_{0}^{t-\epsilon} U(t-\epsilon,s) f(s,z_s+x_s)\,ds.$$
Since $U(t,s)$ is a compact operator, the set
$Z_{\epsilon}(t)=\{F_{\epsilon}(z)(t):  z\in B_d\}$ is pre-compact
in $E$ for every $\epsilon$, $0<\epsilon<t$. Moreover
$$
|F(z)(t)-F_{\epsilon}(z)(t)|\leq
\int_{t-\epsilon}^{t}\|U(t,s)\|_{B(E)}|f(s,z_s+x_s)|ds.
$$
Using $\| z_{s}+x_{s}\|_{\mathcal{B}}\leq D_n$ in \eqref{zsxs} and
the nondecreasing character of $\psi$, we get
$$
|F(z)(t)-F(z)_\epsilon(t)|
\leq\widehat{M}\psi(D_n)\int_{t-\epsilon}^{t}p(s)ds.
$$
Therefore the set $Z(t)=\{F(z)(t): z\in B_d\}$ is totally bounded.
Hence the set $\{F(z)(t): z \in B_d\}$ is relatively compact $E$. So
we deduce from Steps 1, 2 and 3 that $F$ is a compact operator.

\noindent {\bf Step 4:} $G$ is a contraction mapping.
Let $z,\overline{z}\in B^0_{+\infty}$, then
using (H1) and (H3) for each $t\in [0,n] $ and $n\in \mathbb{N}$
\begin{align*}
|G(z)(t)-G(\overline{z} )(t)|
&\leq \int_{0}^{t}\|U(t,s)\|_{B(E)}
|g(s,z_s+x_s)-g(s,\overline{z}_s+x_s)|\,ds\\
&\leq \int_{0}^{t}\widehat{M} \eta(s) \|
z_s+x_s-\overline{z}_s-x_s\|_{\mathcal{B}}\,ds\\
&\leq \int_{0}^{t}\widehat{M} \eta(s) \|
z_s-\overline{z}_s\|_{\mathcal{B}}\,ds.
\end{align*}
Using (A1), we obtain
\begin{align*}
|G(z)(t)-G(\overline{z} )(t)|&\leq \int_{0}^{t}\widehat{M}
\eta(s) (K(s) | z(s)-\overline{z}(s)|+M(s) \|
z_0-\overline{z}_0\|_{\mathcal{B}})\,ds\\
&\leq \int_{0}^{t} \widehat{M}K_n \eta (s) | z(s)-\overline{z}(s)|\,ds\\
&\leq \int_{0}^{t} [\overline{l}_n(s) e^{\tau
L_n^{\ast}(s)} ] [e^{-\tau  L_n^{\ast}(s)} |
z(s)-\overline{z}(s)| ]\,ds\\
&\leq \int_{0}^{t}\big[\frac{e^{\tau  L_n^{\ast
}(s)}}{\tau }\big]'\,ds \| z-\overline{z} \|_n\\
&\leq \frac{1}{\tau } e^{\tau  L_n^{\ast }(t)} \|
z-\overline{z} \|_n.
\end{align*}
Therefore,
$$
\| G(z)-G(\overline{z} )\|_n \leq \frac{1}{\tau } \| z-\overline{z}
\|_n.
$$
So, the operator $G$ is a contraction for all $n\in\mathbb{N} $.

\noindent{\bf Step 5:} For applying Theorem \ref{th1},
we must check (S2): i.e. it remains to show that the set
$$
\mathcal{E}=\{ z\in B_{+\infty}^0:z=\lambda F(z)+\lambda G\big(
\frac{z}{\lambda}\big)\text{ for some } 0<\lambda
<1\}
$$
is bounded.
Let $z\in \mathcal{E}$. By (H1)--(H3), we have for each $t\in [0,n]$
\begin{align*}
|z(t)|&\leq \int_{0}^{t}\|U(t,s)\|_{B(E)}|f(s,z_{s}+x_{s})|ds\\
&\quad+ \int_{0}^{t}\|U(t,s)\|_{B(E)}|g(s,z_{s}+x_{s})-g(s,0)+g(s,0)|ds\\
&\leq \widehat{M}\int_{0}^{t}p(s)\psi\left(\| z_{s}+x_{s}\|_{\mathcal{B}} \right)ds\\
&\quad+ \widehat{M}\int_{0}^{t}\eta(s)\|z_{s}+x_{s}\|_{\mathcal{B}}ds
+\widehat{M}\int_{0}^{t}|g(s,0)|ds.
\end{align*}
Using \eqref{zsxs} we get
$$
\| z_{s}+x_{s}\|_{\mathcal{B}}\leq K_n|z(s)|+c_n.
$$
The nondecreasing character of $\psi$ gives
\begin{align*}
|z(t)|&\leq \widehat{M}\int_{0}^{t}p(s)\psi(K_n|z(s)|+c_n)ds\\
&\quad+ \widehat{M}\int_{0}^{t}\eta(s)(K_n|z(s)|+c_n)ds+\widehat{M}\int_{0}^{t}|g(s,0)|ds.
\end{align*}
Then
\begin{align*}
K_n|z(t)|+c_n&\leq K_n\widehat{M}\int_{0}^{t}p(s)\psi(K_n|z(s)|+c_n)ds\\
&\quad+ K_n\widehat{M}\int_{0}^{t}\eta(s)(K_n|z(s)|+c_n)ds
+ K_n\widehat{M}\int_{0}^{t}|g(s,0)|ds+c_n.
\end{align*}
Set
$$
\alpha_n:=K_n\widehat{M}\int_{0}^{t}|g(s,0)|ds+c_n,
$$
 thus
\begin{align*}
K_n|z(t)|+c_n\leq &K_n\widehat{M}\int_{0}^{t}p(s)\psi(K_n|z(s)|+c_n)ds\\
& + K_n\widehat{M}\int_{0}^{t}\eta(s)(K_n|z(s)|+c_n)ds+\alpha_n.
\end{align*}
We consider the function $\mu $ defined by
$$
\mu (t):=\sup \{ K_n|z(s)|+c_n: 0\leq s\leq t \},\quad
0\leq t<+\infty.
$$
Let $t^{\star}\in[0,t]$ be such that
$$
\mu (t)=K_n|z(t^{\star})|+c_n,
$$
by the previous inequality, we have
\[
\mu (t)\leq  K_n\widehat{M}\int_{0}^{t}p(s)\psi(\mu(s))ds
+ K_n\widehat{M}\int_{0}^{t}\eta(s)\mu(s)ds+\alpha_n
\]
for $t\in [0,n]$.
Let us denote the right-hand side of the above inequality as $v(t)$.
Then, we have
$$
\mu (t)\leq v(t) \quad \text{for all }  t\in [0,n].
$$
 From the definition of $v$, we have $v(0)=\alpha_n$ and
 $$
v'(t)=K_n\widehat{M}p(t)\psi(\mu(t)) +K_n\widehat{M}\eta(t)\mu(t)
\quad\text{a.e. } t\in [0,n].
$$
Using the nondecreasing character of $\psi $, we get
$$
v'(t)\leq K_n\widehat{M}p(t)\psi(v(t))+K_n\widehat{M}\eta(t)v(t)
\quad\text{a.e. } t\in [0,n].
$$
This implies that for each $t\in [0,n]$ and using $\eqref{cond1}$, we get
\begin{align*}
\int_{\alpha_n}^{v(t) }\frac{ds}{s+\psi
(s)}&\leq K_n\widehat{M}\int_{0}^{t}\max(p(s),\eta(s))ds\\
&\leq K_n\widehat{M}\int_{0}^{n}\max(p(s),\eta(s))ds\\
&< \int_{\alpha_n}^{+\infty}\frac{ds}{s+\psi (s)}.
\end{align*}
Thus, for every $t\in[0,n]$, there exists a constant $N_n$ such that
$v(t)\leq N_n$ and hence $\mu (t)\leq N_n$. Since $\|z\|_n
\leq\mu(t)$, we have $\| z\|_n\leq N_n$. This shows that the set
$\mathcal E$ is bounded. Then statement $(S2)$ in Theorem \ref{th1}
does not hold. The nonlinear alternative of Avramescu implies that
$(S1)$ holds, we deduce that the operator $F+G$ has a fixed-point
$z^{\star}$. Then $y^{\star}(t)=z^{\star}(t)+x(t)$,
$t\in(-\infty,+\infty)$ is a fixed point of the operator $N$, which
is the  mild solution of \eqref{e1}--\eqref{e2}.
\end{proof}

\section{Perturbed Neutral Evolution Equations}

 In this section, we give an existence result
for the perturbed neutral evolution problem with infinite delay
\eqref{e3}--\eqref{e4}. Firstly we define the mild solution.

\begin{definition} \label{ref4.1} \rm
We say that the function $y(\cdot ):\mathbb{R}\to E$ is a mild
solution of \eqref{e3}--\eqref{e4} if $ y(t)=\phi (t)$ for all $t\in
(-\infty,0]$ and $y$ satisfies the integral equation
\begin{equation}\label{nmild}
\begin{aligned}
y(t)&=U(t,0)[\phi (0)-h(0,\phi)]+h(t,y_{t})+\int_{0}^{t}U(t,s)
A(s)h(s,y_{s})ds\\
&\quad +\int_{0}^{t}U(t,s)[f(s,y_s)+g(s,y_s)]\,ds\quad
\text{for each }t\in [0,+\infty).
\end{aligned}
\end{equation}
\end{definition}

In what follows we  need the following assumptions:
\begin{itemize}
\item[(H4)] There exists a constant $\overline M_0>0$ such that
$$
\| A^{-1}(t)\|_{B(E)}\leq \overline M_0\quad\text{for all }t\in J.
$$

\item[(H5)] There exists a constant $0<L<\frac{1}{\overline M_0K_n}$ such
that
$$
|A(t) h(t,\phi)| \leq L (\| \phi \|_{\mathcal{B}}+1) \quad
 \text{for all } t\in J,\; \phi\in \mathcal{B}.
$$

\item[(H6)] There exists a constant $L_{*}>0$ such that
$$
| A(s) h(s,\phi)-A(\overline s) h(\overline{s},\overline{\phi})|\leq
L_{*} (|s-\overline{s}|+\| \phi-\overline{\phi}\|_{\mathcal{B}})
$$
for all $s,\overline{s}\in J$ and
$\phi,\overline{\phi}\in \mathcal{B}$.
\end{itemize}

\begin{theorem}\label{th3}
Suppose that hypotheses {\rm (H1)--(H6)} are satisfied and
\begin{equation}\label{cond2}
\int_{\zeta_n}^{+\infty}\frac{ds}{s+\psi
(s)}>\frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}
\int_{0}^{n}\max(L,\eta(s),p(s))ds\quad\text{for each } n\in\mathbb{N}
\end{equation}
with
\[
\zeta_n:= \frac{K_n}{1-\overline{M}_0LK_n}
\Big[\overline{M}_0L\big(1+\widehat{M}+c_n+\widehat{M}\|\phi
\|_{\mathcal{B}}\big)+ \widehat{M}Ln+\widehat{M}\int_{0}^{t}|g(s,0)|\,ds\Big]+c_n,
\]
 and
$c_n:=(K_n\widehat{M}H+M_n)\|\phi\|_{\mathcal{B}}$.
 Then \eqref{e3}--\eqref{e4} has a mild solution.
\end{theorem}

\begin{proof} Consider the operator $\widetilde{N}: B_{+\infty}\to
B_{+\infty}$ defined by
\begin{equation}\label{e12}
\widetilde{N}(y)(t)
=\begin{cases}
\phi(t),&\text{if }t\in(-\infty,0]; \\
 U(t,0) [\phi (0)-h(0,\phi)]+h(t,y_{t})\\
+\int_{0}^{t}U(t,s)A(s)h(s,y_{s})ds \\
+\int_{0}^{t}U(t,s)[f(s,y_s)+g(s,y_s)]ds,&
 \text{if } t\in J.
\end{cases}
\end{equation}

Note that the fixed points of the operator $\widetilde{N}$ are mild solutions
of  \eqref{e3}--\eqref{e4}.
For $\phi \in \mathcal{B}$, we  define the function
$x:\mathbb{R}\to E$ by
\[
x(t)=\begin{cases}
\phi(t), &\text{if } t\in (-\infty,0];\\
 U(t,0) \phi(0),&\text{if } t\in J.
\end{cases}
\]
Then $x_{0}=\phi$. For each function $z\in B_{+\infty}$, set
\begin{equation}
y(t)=z(t)+x(t).
\end{equation}
It is obvious that $y$ satisfies \eqref{nmild} if and only if $z$
satisfies $z_0=0$. For $t\in J$, we get
\begin{align*}
z(t)&= h(t,z_t+x_t)-U(t,0)h(0,\phi)+\int_{0}^{t}U(t,s)A(s)h(s,z_s+x_s)ds\\
&\quad+ \int_{0}^{t}U(t,s)f(s,z_s+x_s)ds+\int_{0}^{t}U(t,s)g(s,z_s+x_s)ds.
\end{align*}
Define the operators $\widetilde{F},\widetilde{G}:B_{+\infty}^0\to
B_{+\infty}^0$ by
\begin{equation}\label{F2}
\widetilde{F}(z)(t)=\int_{0}^{t}U(t,s)f(s,z_s+x_s)ds
\end{equation}
and
\begin{equation}\label{G}
\begin{aligned}
\widetilde{G}(z)(t)&=h(t,z_t+x_t)-U(t,0)h(0,\phi)
+\int_{0}^{t}U(t,s)A(s)h(s,z_s+x_s)ds\\
&\quad +\int_{0}^{t}U(t,s)g(s,z_s+x_s)ds.
\end {aligned}
\end{equation}
Obviously the operator $\widetilde{N}$ having a fixed point is
equivalent to $\widetilde{F}+\widetilde{G}$ having a fixed point.
The proof that $\widetilde{F}+\widetilde{G}$ has a fixed point is
done in several steps.

\noindent {\bf Step 1:} $\widetilde{F}$ is continuous and compact. This can
 be shown as we did for $F$ in Section 3.

\noindent{\bf Step 2:} $\widetilde{G}$ is a contraction mapping. Let
$z,\overline{z}\in B^0_{+\infty}$, then using (H1), (H3)--(H6) for
each $t\in [0,n] $ and $n\in \mathbb{N}$,
\begin{align*}
&|\widetilde{G}(z)(t)-\widetilde{G}(\overline{z} )(t)|\\
&\leq |h(t,z_t+x_t)-h(t,\overline{z}_t+x_t)|\\
&\quad+ \int_{0}^{t}\|U(t,s)\|_{B(E)}|A(s)[h(s,z_s+x_s)-h(s,\overline{z}_s+x_s)]|\,ds\\
&\quad+ \int_{0}^{t}\|U(t,s)\|_{B(E)}|g(s,z_s+x_s)-g(s,\overline{z}_s+x_s)|\,ds\\
&\leq \|A^{-1}(s)\||A(t)h(t,z_t+x_t)-A(t)h(t,\overline{z}_t+x_t)|\\
&\quad+ \int_{0}^{t}\widehat{M}|A(s)h(s,z_s+x_s)-A(s)h(s,\overline{z}_s+x_s)|\,ds\\
&\quad+ \int_{0}^{t}\widehat{M}|g(s,z_s+x_s)-g(s,\overline{z}_s+x_s)|\,ds\\
&\leq \overline M_0L_*\|z_t+x_t-\overline{z}_t-x_t\|_{\mathcal{B}}
+\int_{0}^{t}\widehat{M}L_*\|z_s+x_s-\overline{z}_s-x_s\|_{\mathcal{B}}\,ds\\
&\quad+ \int_{0}^{t}\widehat{M}
\eta(s)\|z_s+x_s-\overline{z}_s-x_s\|_{\mathcal{B}}\,ds\\
&\leq \overline M_0L_*\|z_t-\overline{z}_t\|_{\mathcal{B}}
+\int_{0}^{t}\widehat{M}[L_*+\eta(s)]\|z_s-\overline{z}_s\|_{\mathcal{B}}\,ds.
\end{align*}
Using  (A1), we obtain
\begin{align*}
|\widetilde{G}(z)(t)-\widetilde{G}(\overline{z} )(t)| &\leq
\overline
M_0L_*\big(K(t)|z(t)-\overline{z}(t)|+M(t)\|z_0-\overline{z}_0
\|_{\mathcal{B}}\big)\\
&\quad+ \int_{0}^{t}\widehat{M}[L_*+\eta(s)]
\big(K(s)|z(s)-\overline{z}(s)|+M(s)\|z_0-\overline{z}_0
\|_{\mathcal{B}}\big)\,ds\\
&\leq \overline M_0L_*K_n|z(t)-\overline{z}(t)|
+\int_{0}^{t}\widehat{M}K_n[L_*+\eta(s)]|z(s)-\overline{z}(s)|\,ds.
\end{align*}
Let $\overline{l}_n(t)=\widehat{M}K_n[L_*+\eta(t)]$
for the family seminorms $\{\|\cdot\|_n\}_{n\in\mathbb{N}}$.
Then
\begin{align*}
|\widetilde{G}(z)(t)-\widetilde{G}(\overline{z} )(t)|&\leq \overline
M_0L_*K_n|z(t)-\overline{z}(t)|
+\int_{0}^{t}\overline{l}_n(s)]|z(s)-\overline{z}(s)|\,ds\\
&\leq \big[ \overline
 M_0L_{*}K_n e^{\tau L_n^{*}(t)}\big]
\big[e^{-\tau
L_n^{*}(t)} |z(t)-\overline{z}(t)|\big]\\
&\quad+ \int_{0}^{t}\big[\overline{l}_n(s) e^{\tau
L_n^{*}(s)}\big] \big[e^{-\tau
L_n^{*}(s)} |z(s)-\overline{z}(s)|\big]ds\\
&\leq \overline M_0L_{*}K_n e^{\tau L_n^{*}(t)}
\|z-\overline{z}\|_n
+\int_{0}^{t}\big[\frac{e^{\tau  L_n^{*}(s)}}{\tau}\big]'\,ds
 \|z-\overline{z}\|_n\\
&\leq \overline M_0L_{*}K_n e^{\tau L_n^{*}(t)}
\|z-\overline{z}\|_n
+\frac{1}{\tau} e^{\tau  L_n^{*}(t)} \|z-\overline{z}\|_n\\
&\leq \big[\overline M_0L_{*}K_n+\frac{1}{\tau}\big] e^{\tau
L_n^{*}(t)} \|z-\overline{z}\|_n.
\end{align*}
Therefore,
$$
\| \widetilde{G}(z)-\widetilde{G}(\overline{z} )\|_n \leq [\overline
M_0L_{*}K_n+\frac{1}{\tau}] \| z-\overline{z} \|_n.$$

So, for $[\overline M_0L_{*}K_n+\frac{1}{\tau}]<1$, the operator
$\widetilde{G}$ is a contraction for all $n\in \mathbb{N} $.

\noindent{\bf Step 3:} The set
$$
\widetilde{\mathcal{E}}=\big\{ z\in B_{+\infty}^0:z=\lambda
\widetilde{F}(z)+\lambda \widetilde{G} \big(
\frac{z}{\lambda}\big)\quad \text{for some }
 0<\lambda <1\big\}
$$
is bounded. Let $z\in \widetilde{\mathcal{E}}$. Then, we have
\begin{align*}
|z(t)|&\leq |h(t,z_t+x_t)|+\|U(t,0)\|_{B(E)}|h(0,\phi)|\\
&\quad+ \int_{0}^{t}\|U(t,s)\|_{B(E)}|A(s)h(s,z_s+x_s)|\,ds\\
&\quad+ \int_{0}^{t}\|U(t,s)\|_{B(E)}|f(s,z_s+x_s)|\,ds\\
&\quad+ \int_{0}^{t}\|U(t,s)\|_{B(E)}|g(s,z_s+x_s)-g(s,0)+g(s,0)|\,ds.
\end{align*}
By  (A1) and  (H1)--(H6), we have
\begin{align*}
|z(t)|
&\leq \|A^{-1}(s)\||A(t)h(t,z_t+x_t)|+\widehat{M}\|A^{-1}(s)\||A(t)h(0,\phi)|\\
&\quad+ \widehat{M}\int_{0}^{t}|A(s)h(s,z_s+x_s)|\,ds+\widehat{M}\int_{0}^{t}f(s,z_s+x_s)\,ds\\
&\quad+ \widehat{M}\int_{0}^{t}|g(s,z_s+x_s)-g(s,0)|\,ds+\widehat{M}\int_{0}^{t}|g(s,0)|\,ds\\
&\leq \overline{M}_0L(\|z_t+x_t\|_{\mathcal{B}}+1)+\widehat{M}\overline{M}_0L(\|\phi\|_{\mathcal{B}}+1)\\
&\quad+ \widehat{M}L\int_{0}^{t}(\|z_s+x_s\|_{\mathcal{B}}+1)\,ds+\widehat{M}\int_{0}^{t}p(s)\psi(\|z_s+x_s)\|_{\mathcal{B}})\,ds\\
&\quad+ \widehat{M}\int_{0}^{t}\eta(s)\|z_s+x_s\|_{\mathcal{B}}\,ds+\widehat{M}\int_{0}^{t}|g(s,0)|\,ds\\
&\leq \overline{M}_0L\|z_t+x_t\|_{\mathcal{B}}
 +\overline{M}_0L+\widehat{M}\overline{M}_0L+\widehat{M}Ln+
\widehat{M}\overline{M}_0L\|\phi\|_{\mathcal{B}}\\
&\quad+ \widehat{M}\int_{0}^{t}|g(s,0)|\,ds+\widehat{M}L\int_{0}^{t}\|z_s+x_s\|_{\mathcal{B}}\,ds\\
&\quad+ \widehat{M}\int_{0}^{t}p(s)\psi(\|z_s+x_s)\|_{\mathcal{B}})\,ds+\widehat{M}\int_{0}^{t}\eta(s)\|z_s+x_s\|_{\mathcal{B}}\,ds.
\end{align*}
Using $\| z_{s}+x_{s}\|_{\mathcal{B}}\leq K_n|z(s)|+c_n$ in
\eqref{zsxs} and the nondecreasing character of $\psi$, we get
\begin{align*}
|z(t)|&\leq \overline{M}_0L(K_n|z(t)|+c_n)+\overline{M}_0L
+\widehat{M}\overline{M}_0L+\widehat{M}Ln+
\widehat{M}\overline{M}_0L\|\phi\|_{\mathcal{B}}\\
&\quad+ \widehat{M}\int_{0}^{t}|g(s,0)|\,ds+\widehat{M}L
 \int_{0}^{t}(K_n|z(s)|+c_n)\,ds\\
&\quad+ \widehat{M}\int_{0}^{t}p(s)\psi(K_n|z(s)|+c_n)\,ds
 +\widehat{M}\int_{0}^{t}\eta(s)(K_n|z(s)|+c_n)\,ds.
\end{align*}
Then
\begin{align*}
(1-\overline{M}_0LK_n)|z(t)|&\leq \overline{M}_0L(c_n+1
+\widehat{M}[1+\|\phi\|_{\mathcal{B}}])
+\widehat{M}Ln\\ &\quad+ \widehat{M}\int_{0}^{t}|g(s,0)|\,ds
+\widehat{M}L\int_{0}^{t}(K_n|z(s)|+c_n)\,ds\\
&\quad+ \widehat{M}\int_{0}^{t}p(s)\psi(K_n|z(s)|+c_n)\,ds\\
&\quad+ \widehat{M}\int_{0}^{t}\eta(s)(K_n|z(s)|+c_n)\,ds.
\end{align*}
Set
\[
\zeta_n:= \frac{K_n}{1-\overline{M}_0LK_n}
\Big[\overline{M}_0L\big(1+\widehat{M}+c_n+\widehat{M}\|\phi\|_
{\mathcal{B}}\big)
+ \widehat{M}Ln+\widehat{M}\int_{0}^{t}|g(s,0)|\,ds\Big]+c_n.
\]
 Thus
\begin{align*}
K_n|z(t)|+c_n
&\leq \zeta_n+\frac{\widehat{M}LK_n}{1-\overline{M}_0LK_n}
 \int_{0}^{t}(K_n|z(s)|+c_n)\,ds\\
&\quad+ \frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}
 \int_{0}^{t}p(s)\psi(K_n|z(s)|+c_n)\,ds\\
&\quad+ \frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}
 \int_{0}^{t}\eta(s)(K_n|z(s)|+c_n)\,ds.
\end{align*}
Consider the function $\mu $ defined by
$$
\mu (t):=\sup\{ K_n|z(s)|+c_n: 0\leq s\leq t \},\quad 0\leq t<+\infty.
$$
Let $t^{\star}\in[0,t]$ be such that
$\mu (t)=K_n|z(t^{\star})|+c_n$, by the previous inequality,
we have
\begin{align*}
\mu
(t)&\leq \zeta_n+\frac{\widehat{M}LK_n}{1-\overline{M}_0LK_n}
 \int_{0}^{t}\mu(s)\,ds+\frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}
 \int_{0}^{t}\eta(s)\mu(s)\,ds\\
&\quad+ \frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}\int_{0}^{t}p(s)
 \psi(\mu(s))\,ds \quad \text{for } t\in [0,n].
\end{align*}
Let us denote the right-hand side of the above inequality as $v(t)$.
Then, we have
$$
\mu (t)\leq v(t) \quad \text{for all }  t\in [0,n].
$$
From the definition of $v$, we have $v(0)=\zeta_n$ and
$$
v'(t)=\frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}
[L\mu(t)+\eta(t)\mu(t)+p(t)\psi(\mu(t))]
 \quad\text{a.e. } t\in [0,n].
$$
Using the nondecreasing character of $\psi $, we get
$$
v'(t)\leq \frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}
[Lv(t)+\eta(t)v(t)+p(t)\psi(v(t))] \quad\text{a.e. }
t\in [0,n].
$$
This implies that for each $t\in [0,n]$ and using the condition
\eqref{cond2}, we get
\begin{align*}
\int_{\zeta_n}^{v(t) }\frac{ds}{s+\psi (s)}
&\leq \frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}\int_{0}^{t}
 \max(L,\eta(s),p(s))ds\\
&\leq \frac{\widehat{M}K_n}{1-\overline{M}_0LK_n}\int_{0}^{n}
 \max(L,\eta(s),p(s))ds\\
&< \int_{\zeta_n}^{+\infty}\frac{ds}{s+\psi (s)}.
\end{align*}
Thus, for every $t\in[0,n]$, there exists a constant
$\widetilde{N}_n$ such that $v(t)\leq \widetilde{N}_n$ and hence
$\mu (t)\leq \widetilde{N}_n$. Since $\|z\|_n \leq\mu(t)$, we have
$\| z\|_n\leq \widetilde{N}_n$. This shows that the set
$\widetilde{\mathcal E}$ is bounded. Then the statement (S2) in
Theorem \ref{th1} does not hold. The nonlinear alternative of
Avramescu implies that (S1) holds, we deduce that the operator
$\widetilde{F}+\widetilde{G}$ has a fixed-point $z^{\star}$. Then
$y^{\star}(t)=z^{\star}(t)+x(t)$, $t\in(-\infty,+\infty)$ is a fixed
point of the operator $\widetilde{N}$, which is the mild solution of
\eqref{e3}--\eqref{e4}.
\end{proof}

\section{Applications}

 To illustrate the previous results, we give in this section
two applications.

\begin{example} \label{exa5.1} \rm
 Consider the  model
\begin{equation}\label{Expl1}
\begin{gathered}
\begin{aligned}
\frac{\partial v}{\partial t}(t,\xi)
&=a(t,\xi)\frac{\partial ^{2}v}{\partial \xi^{2}}(t,\xi)
 +\int^0_{-\infty}P(\theta)r(t,v(t+\theta,\xi))d\theta\\
&\quad +\int^0_{-\infty}Q(\theta)s(t,v(t+\theta,\xi))d\theta, \quad
t \in[0,+\infty),\; \xi\in [0,\pi ]
\end{aligned}\\
 v(t,0)= v(t,\pi ) =0\quad  t \in[0,+\infty) \\
 v(\theta,\xi) = v_0(\theta,\xi)\quad -\infty<\theta\leq 0,\;
\xi\in [0,\pi ],
\end{gathered}
\end{equation}
where $a(t,\xi)$ is a continuous function and is uniformly
H\"{o}lder continuous in $t$; $P,Q:(-\infty,0]\to\mathbb{R}$;
$r,s:[0,+\infty)\times\mathbb{R}\to\mathbb{R}$ and
$v_0:(-\infty,0]\times[0,\pi]\to\mathbb{R}$ are continuous
functions.
\end{example}

 Consider $E=L^{2}([0,\pi],\mathbb{R})$ and define $A(t)$
by $A(t)w=a(t,\xi)w''$ with domain
$$
D(A)=\{ w\in E : w, w'  \text{ are absolutely continuous, }
w''\in E,\; w(0)=w(\pi)=0 \}
$$
Then $A(t)$ generates an evolution system $U(t,s)$ satisfying
assumption (H1) (see \cite{Fre}).

 For the phase space $\mathcal{B}$, we choose the well
known space $BUC({\mathbb{R}}^{-},E)$, the space of uniformly bounded
continuous functions endowed with the  norm
$$
\| \varphi \|=\sup_{\theta {\leq }0}|\varphi (\theta
)|\quad \text{for }\varphi \in \mathcal{B}.
$$
If we put for $\varphi\in BUC({\mathbb{R}}^{-},E)$ and
$\xi\in[0,\pi]$,
\begin{gather*}
y(t)(\xi)=v(t,\xi), \quad t\in [0,+\infty), \; \xi\in [0,\pi],\\
\phi(\theta)(\xi)=v_0(\theta,\xi), \quad -\infty<\theta\leq0, \; \xi\in
[0,\pi],\\
f(t,\varphi)(\xi)=\int^0_{-\infty}P(\theta)r(t,\varphi(\theta)(\xi))d\theta,
\quad -\infty<\theta\leq0, \; \xi\in [0,\pi], \\
g(t,\varphi)(\xi)=\int^0_{-\infty}Q(\theta)s(t,\varphi(\theta)(\xi))d\theta,
\quad -\infty<\theta\leq0, \; \xi\in [0,\pi].
\end{gather*}
Then,  \eqref{Expl1} takes the abstract partial perturbed evolution
form \eqref{e1}--\eqref{e2}. To show the existence of mild solutions
to \eqref{Expl1}, we assume the following hypotheses:

\begin{itemize}
\item The function $s$ is Lipschitz continuous with respect to its
second argument. Let $lip(s)$ denote
the Lipschitz constant of $s$.

\item There exist $p\in L^{1}([0,+\infty),\mathbb{R}^{+})$ and a nondecreasing
continuous function $\psi :[0,+\infty)\to (0,\infty)$ such that
$$
| r(t,u)| \leq p(t)\psi (|u| ), \quad \text{for }  t\in [0,+\infty),
\;  u\in \mathbb{R}.
$$

\item $P$ and $Q$ are integrable on $(-\infty,0]$.
\end{itemize}

By the dominated convergence theorem, one can show that $f$ is a
continuous function from $\mathcal{B}$ to $E$. Moreover the mapping $g$
is Lipschitz continuous in its second argument, in fact, we have
$$
| g(t,\varphi _{1})-g(t,\varphi _{2})| \leq
\mathop{\rm lip}(s)\int_{-\infty }^{0}| Q(\theta )|\, d\theta
|\varphi _{1}-\varphi _{2}| ,\quad \text{for }
\varphi _{1},\varphi_{2}\in \mathcal{B}.
$$
On the other hand,  for $\varphi \in \mathcal{B}$ and
$\xi \in [ 0,\pi ] $ we have
$$
| f(t,\varphi )(\xi )| \leq \int_{-\infty }^{0}
|p(t)P(\theta )| \psi (| (\varphi (\theta)) (\xi )|)d\theta.
$$
Since the function $\psi$ is nondecreasing, it follows that
$$
| f(t,\varphi )| \leq p(t)\int_{-\infty }^{0}
|P(\theta )| d\theta \psi (| \varphi| ),\quad \text{
for }\varphi \in \mathcal{B}.
$$

\begin{proposition} \label{prop5.1}
Under the above assumptions, if we assume that condition
\eqref{cond1} in Theorem \ref{th2} is true, $\varphi \in \mathcal{B}$, then the problem
\eqref{Expl1} has a mild solution which is defined in
$(-\infty ,+\infty)$.
\end{proposition}

\begin{example} \label{exa5.2} \rm
Consider the  model
\begin{equation}\label{Expl2}
\begin{gathered}
\begin{aligned}
\frac{\partial }{\partial t}&\big[v(t,\xi)
-\int_{-\infty}^{0}T(\theta)u(t,v(t+\theta,\xi))d\theta\big] \\
&=a(t,\xi)\frac{\partial ^{2}v}{\partial \xi^{2}}(t,\xi)
 +\int^0_{-\infty}P(\theta)r(t,v(t+\theta,\xi))d\theta \\
&\quad +\int^0_{-\infty}Q(\theta)s(t,v(t+\theta,\xi))d\theta \quad
t \in[0,+\infty),\quad  \xi\in [0,\pi ]
\end{aligned}\\
v(t,0) = v(t,\pi ) =0,\quad  t \in[0,+\infty) \\
v(\theta,\xi) = v_0(\theta,\xi),\quad -\infty<\theta\leq0, \;
 \xi\in [0,\pi ],
\end{gathered}
\end{equation}
where $a(t,\xi)$ is a continuous function and is uniformly
H\"{o}lder continuous in $t$; $T,P,Q:(-\infty,0]\to\mathbb{R}$;
$u,r,s:[0,+\infty)\times\mathbb{R}\to\mathbb{R}$ and
$v_0:(-\infty,0]\times[0,\pi]\to\mathbb{R}$ are continuous
functions.
\end{example}

 Consider $E=L^{2}([0,\pi],\mathbb{R})$ and define $A(t)$
by $A(t)w=a(t,\xi)w''$ with domain
$$
D(A)=\{w\in E: w,\; w'  \text{ are absolutely continuous },
 w''\in E,\; w(0)=w(\pi)=0\}
$$
Then $A(t)$ generates an evolution system $U(t,s)$ satisfying
assumptions (H1) and (H4) (see \cite {Fre}).

 For the phase space $\mathcal{B}$, we choose the well
known space $BUC({\mathbb{R}}^{-},E)$ : the space of uniformly bounded
continuous functions endowed with the norm
$$
\| \varphi \|=\sup_{\theta {\leq }0}|\varphi (\theta)|\quad
 \text{for } \varphi \in \mathcal{B}.
$$
If we put for $\varphi\in BUC({\mathbb{R}}^{-},E)$ and
$\xi\in[0,\pi]$,
\begin{gather*}
y(t)(\xi)=v(t,\xi), \quad t\in [0,+\infty), \; \xi\in [0,\pi], \\
\phi(\theta)(\xi)=v_0(\theta,\xi), \quad -\infty<\theta\leq0, \;
 \xi\in [0,\pi],\\
h(t,\varphi)(\xi)=\int^0_{-\infty}T(\theta)u(t,\varphi(\theta)(\xi))d\theta,
\quad -\infty<\theta\leq0, \; \xi\in [0,\pi], \\
f(t,\varphi)(\xi)=\int^0_{-\infty}P(\theta)r(t,\varphi(\theta)(\xi))d\theta,
\quad -\infty<\theta\leq0, \; \xi\in [0,\pi] \\
g(t,\varphi)(\xi)=\int^0_{-\infty}Q(\theta)s(t,\varphi(\theta)(\xi))d\theta,
 \quad -\infty<\theta\leq0,  \xi\in [0,\pi].
\end{gather*}
 Then,  (\ref{Expl2}) takes the abstract
neutral perturbed evolution form \eqref{e3}--\eqref{e4}.
To show the existence of the  mild solution to
(\ref{Expl2}), we assume the following hypotheses:

\begin{itemize}
\item the functions $u$ and $s$ are Lipschitz with respect to its second
argument, and constants $\mathop{\rm lip}(u)$  and $\mathop{\rm lip}(s)$
 respectively.

\item There exist $p\in L^{1}([0,+\infty),\mathbb{R}^{+})$ and a nondecreasing
continuous function $\psi :[0,+\infty)\to (0,\infty)$ such that
$$
| r(t,u)| \leq p(t)\psi (|u| ), \quad \text{for }  t\in [0,+\infty),
\;
  u\in \mathbb{R}.
$$

\item $T$, $P$ and $Q$ are integrable on $(-\infty,0]$.
\end{itemize}

By the dominated convergence theorem, one can show that $f$ is a
continuous function from $\mathcal{B}$ to $E$. Moreover the mapping $h$
and $g$ are Lipschitz continuous in its second argument, in fact, we
have
\begin{gather*}
| g(t,\varphi _{1})-g(t,\varphi _{2})| \leq
\mathop{\rm lip}(s)\int_{-\infty }^{0}| Q(\theta )| d\theta
| \varphi _{1}-\varphi _{2}| ,\quad \text{ for }\varphi _{1},\varphi
_{2}\in \mathcal{B},\\
|h(t,\varphi _{1})-h(t,\varphi _{2})| \leq
\overline{M}_0L_*\mathop{\rm lip}(u)\int_{-\infty }^{0}| T(\theta )|
d\theta | \varphi _{1}-\varphi _{2}| ,\quad \text{for }\varphi
_{1},\varphi _{2}\in \mathcal{B}.
\end{gather*}
On the other hand,  for $\varphi \in \mathcal{B}$ and
$\xi \in [ 0,\pi ] $ we have
$$
| f(t,\varphi )(\xi )| \leq \int_{-\infty }^{0}
| p(t)P(\theta )| \psi (| (\varphi (\theta)) (\xi )|)d\theta.
$$
Since the function $\psi$ is nondecreasing, it follows that
$$
| f(t,\varphi )| \leq p(t)\int_{-\infty }^{0} |P(\theta )| d\theta
\psi (| \varphi| ),\quad \text{for }\varphi \in \mathcal{B}.
$$

\begin{proposition} \label{prop5.2}
Under the above assumptions, if we assume that condition
(\ref{cond2}) in Theorem \ref{th3} is true, $\varphi \in \mathcal{B}$,
then \eqref{Expl2} has a mild solution which is defined in
$(-\infty ,+\infty)$.
\end{proposition}


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\end{document}