\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2015 (2015), No. 42, pp. 1--21.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2015 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2015/42\hfil Favard spaces and admissibility]
{Favard spaces and admissibility for Volterra systems with
scalar kernel}

\author[H. Bounit, A. Fadili \hfil EJDE-2015/42\hfilneg]
{Hamid Bounit, Ahmed Fadili}

\address{Hamid Bounit \newline
Department of Mathematics, Faculty of Sciences,
Ibn Zohr University,  BP 8106,
Agadir 80 000, Morocco}
\email{h.bounit@uiz.ac.ma}

\address{Ahmed Fadili \newline
Department of Mathematics, Faculty of Sciences,
Ibn Zohr University,  BP 8106,
Agadir 80 000, Morocco}
\email{ahmed.fadili@edu.uiz.ac.ma}

\thanks{Submitted March 22, 2014. Published February 12, 2015.}
\subjclass[2000]{45D05, 45E05, 45E10, 47D06}
\keywords{Semigroups; Volterra integral equations; resolvent family;
\hfill\break\indent Favard space; admissibility}

\begin{abstract}
 We introduce the Favard spaces for resolvent families, extending some
 well-known theorems for semigroups. Furthermore, we show the relationship
 between these Favard spaces and the $L^p$-admissibility of control
 operators for scalar Volterra linear systems in Banach spaces, extending
 some results in \cite{Maragh2014}. Assuming that the kernel $a(t)$ is
 a creep function which satisfies $a(0^+)>0$, we prove an analogue
 version of the Weiss conjecture for scalar Volterra linear systems
 when $p=1$. To this end, we also show that the finite-time and infinite-time
 (resp. finite-time and uniform finite-time) $L^{1}$-admissibility
 coincide for exponentially stable resolvent families (reps. for reflexive
 state space), extending well-known results for semigroups.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{proposition}[theorem]{Proposition}
\newtheorem{remark}[theorem]{Remark}
\newtheorem{definition}[theorem]{Definition}
\newtheorem{corollary}[theorem]{Corollary}
\newtheorem{example}[theorem]{Example}
\newtheorem{claim}[theorem]{Claim}
\allowdisplaybreaks


\section{Introduction}

Several authors have investigated the notion of the admissibility
of control operator for semigroups 
\cite{HoRussell83,JacobParting2004a, JACPART2001,LeMerdy2003, staffans2005,
G.Weiss;1989a,G.Weiss;1989c}.
The first studies on admissibility of control operator for Volterra
scalar systems began with the paper of Jung \cite{JUN2000}. Later,
admissibility for linear Volterra scalar systems have been discussed
by a number of authors in \cite{Haak2009,Jacob2004b,JACPRT2007}.
In \cite{JUN2000}, Jung links the notion of finite-time $L^{2}$-admissibility
for Volterra scalar system with finite-time $L^{2}$-admissibility
of the well-studied semigroups case for completely positive kernel.
Likewise, in \cite{Jacob2004b} the infinite-time $L^{2}$-admissibility
for a Volterra scalar system is linked with the infinite-time $L^{2}$-admissibility
for semigroups for a large class of kernel and the result subsumes
that of \cite{JUN2000}. In \cite{JACPRT2007}, the authors have given
necessary and sufficient condition for finite-time $L^{2}$-admissibility
of a linear integrodifferential Volterra scalar system when the underlying
semigroup is equivalent to a contraction semigroup, which generalizes
an analogous result known to hold for the standard Cauchy problem
and it subsumes the result in \cite{JUN2000}. Another result is related
to the case where the generator of the underlying semigroup has a
Riesz basis of eigenvectors in \cite{Haak2009}.
 In Section 2, we
give some preliminaries about the concept of resolvent family, and
the relationship between linear integral equation of Volterra type
with scalar kernel. It is well-known that for a Cauchy problem there
are strong relations connecting its semigroup solution and its associated
generator. Likewise, for a Volterra scalar problem, there are some
results connecting its resolvent family and the domain of the associated
generator; which will be reviewed in Section 3. There are many results
available from semigroups theory concerning the Favard spaces (see.
\cite{Butzer1967,EngelNagel;2000}). In Section 4, we define the Favard
spaces for scalar Volterra integral equations, and for these spaces
we account for some results which are similar to those of semigroups.
Especially, we account for a similar result to
 that in \cite[Theorem 9]{DeschSchappacher;1989}
if the kernel is a creep function. In Section 5, we introduce the
ideas of $L^p$-admissibility of resolvent families in the same
spirit of semigroups and we describe the relationship between the
$L^p$-admissibility to the Favard spaces, already introduced in
Section 4. This extends some results obtained for the semigroups case
in \cite{Maragh2014}. In particular, we are able to prove that for
Volterra scalar systems with a creep kernel $a(t)$ such that $a(0^{+})>0$;
the finite-time and the infinite-time $L^{1}$-admissibility are equivalent
for exponentially stable resolvent family; and if the underlying state
space is reflexive then the finite-time and the uniform finite-time
$L^{1}$-admissibility are also equivalent; extending well-known results
for semigroups for all $p\in[1,\infty[$. (See. \cite{G.Weiss;1989c,Grabowski1995}).


\section{Preliminaries}

In this section we collect some elementary facts about scalar Volterra
equations and resolvent family. These topics have been covered in
detail in \cite{Pruss93}. We refer to these works for reference to
the literature and further information.

Let $(X,\| \cdot\| )$ be a Banach space,
$A$ be a linear closed densely defined operator in $X$ and 
$a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$
is a scalar kernel. We consider the linear Volterra equation
\begin{equation}
\begin{gathered}
x(t)=\int_0^t a(t-s)Ax(s)ds+f(t),\quad  t\geq0,\\
x(0)=x_0\in X,
\end{gathered}\label{eq:pb original}
\end{equation}
where $f\in\mathcal{C}(\mathbb{R}^{+},X)$. 

Since $A$ is a closed operator, we may consider $(X_1,\| x\| _1)$ the 
domain of $A$ equipped with the graph-norm, i.e. $\| x\| _1=\| x\| +\| Ax\| $. 
It is continuously embedded in $X$. If the resolvent set $\rho(A)$ of $A$
is nonempty, $A_1:D(A^{2})\to X_1$, with $A_1x=Ax$, is a closed operator
in $X_1$ and $\rho(A)=\rho(A_1)$.
On the other hand, we may consider $X_{-1}$ the completion of $X$ with respect 
to the norm
\[
\| x\| _{-1}=\| (\mu_0I-A)^{-1}x\| \quad
\text{for some $\mu_0\in\rho(A)$ and all $x\in X$}.
\]
These spaces are independent of the choice of $\mu_0$ and are related
by the following continuous and dense injections
\[
X_1\stackrel{d}{\hookrightarrow}X\stackrel{d}{\hookrightarrow}X_{-1}.
\]
Furthermore, the operator $A:\, D(A)\to X_{-1}$ is continuous
and densely defined, its (unique) extension to $X$ as domain makes
it a closed operator in $X_{-1}$, and it is called $A_{-1}$ and
we have $\rho(A)=\rho(A_{-1})$ (see. e.g. \cite{VanNeerven;1992}).

We define the convolution product of the scalar function $a$ with 
the vector-valued function $f$ by
\[
(a*f)(t):=\int_0^t a(t-s)f(s)ds,\quad t\geq0.
\]

\begin{definition} \label{def2.1} \rm
A function $x\in C(\mathbb{R}^{+},X)$ is called:
\begin{itemize}
\item [(i)] 
strong solution of \eqref{eq:pb original} if $x\in C(\mathbb{R}^{+},X_1)$
and \eqref{eq:pb original} is satisfied.

\item [(ii)] mild solution of \eqref{eq:pb original} if
 $a*x\in C(\mathbb{R}^{+},X_1)$
and
\begin{equation}
x(t)=f(t)+A[a*x](t)\,\, t\geq0.\label{EQUATION1.2}
\end{equation}
\end{itemize}
\end{definition}

Obviously, every strong solution of \eqref{eq:pb original} is a mild
solution. Conditions under which mild solutions are strong solutions
are studied in \cite{Pruss93}.

\begin{definition} \label{def2.2} \rm
Equation \eqref{eq:pb original} is called well-posed if, for each
$v\in D(A)$, there is a unique strong solution $x(t,v)$
on $\mathbb{R}^{+}$ of
\begin{equation}
x(t,v)=v+(a*Ax)(t)\quad t\geq0,\label{EQUA1.3}
\end{equation}
and for a sequence $(v_n)\subset D(A)$, $v_n\to0$
implies $x(t,v_n)\to0$ in $X$, uniformly on
compact intervals.
\end{definition}

\begin{definition} \label{def2.3} \rm
Let $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$. A strongly continuous
family $(S(t))_{t\geq0}\subset\mathcal{L}(X)$;
(the space of bounded linear operators in $X$) is called resolvent
family for equation \eqref{eq:pb original}, if the following three
conditions are satisfied:
\begin{itemize}
\item [(S1)] $S(0)=I$.
\item [(S2)] $S(t)$ commutes with $A$, which means $S(t)D(A)\subset D(A)$
for all $t\geq0$, and $AS(t)x=S(t)Ax$ for all $x\in D(A)$ and $t\geq0$.
\item [(S3)] For each $x\in D(A)$ and all $t\geq0$ the resolvent equations
hold:
\[
S(t)x=x+\int_0^t a(t-s)AS(s)xds.
\]
\end{itemize}
\end{definition}

Note that the resolvent for \eqref{eq:pb original} is uniquely determined.
The proofs of these results and further information on resolvent can
be found in the monograph by Pr\"uss \cite{Pruss93}. We also notice
that the choice of the kernel $a$ classifies different families of
strongly continuous solution operators in $\mathcal{L}(X)$: For instance
when $a(t)=1$, then $S(t)$ corresponds to a $\mathcal{C}_0$-semigroup
and when $a(t)=t$, then $S(t)$ corresponds to cosine operator function.
In particular, when $a(t)=\frac{t^{\alpha-1}}{\Gamma(\alpha)}$
with $0<\alpha\leq2$ and $\Gamma$ denotes the Gamma function, they
are the $\alpha$-times resolvent families studied in \cite{Bajlekova2001}
and corresponds to the solution families for fractional evolution
equations, i.e. evolution equations where the integer derivative with
respect to time is replaced by a derivative of fractional order.

The existence of a resolvent family allows one to find the solution
for the equation \eqref{eq:pb original}. Several properties of resolvent
families have been discussed in \cite{Arendt1992,Pruss93}.

The resolvent family is the central object to be studied in the theory
of Volterra equations. The importance of the resolvent family $S(t)$
is that, if it exists, then the solution $x(t)$ of \eqref{eq:pb original}
is given by the following variation of parameters formula in \cite{Pruss93}:
\begin{equation}
x(t)=\frac{d}{dt}\int_0^t S(t-s)f(s)ds,\label{EQU1.4}
\end{equation}
 for all $t\geq0$, and
\begin{equation}
x(t)=S(t)f(0)+\int_0^t S(t-s)f'(s)ds,\label{EQU1.5}
\end{equation}
 where $t\geq0$ and $f\in W^{1,1}(\mathbb{R}^{+},X)$,
gives us a mild solution for \eqref{eq:pb original}.

The following well-known result \cite[Proposition 1.1]{Pruss93} establishes
the relation between well-posedness and existence of a resolvent family.
In what follows, $\mathcal{R}$ denotes the range of a given operator.

\begin{theorem}\label{thm4} 
Equation \eqref{eq:pb original} is well-posed if and
only if \eqref{eq:pb original} admits a resolvent family $(S(t))_{t\geq0}$.
If this is the case we have in addition $\mathcal{R}(a*S(t))\subset D(A)$,
for all $t\geq0$ and
\begin{equation}
S(t)x=x+A\int_0^t a(t-s)S(s)xds,\label{EQUA1.6}
\end{equation}
 for each $x\in X$, $t\geq0$.
\end{theorem}

From this we obtain that if $(S(t))_{t\geq0}$ is a resolvent family
of \eqref{eq:pb original}, we have $A(a*S)(.)$ is strongly continuous
and the so-called mild solution $x(t)=S(t)x_0$ solves equation
\eqref{eq:pb original} for all $x_0\in X$ with $f(t)=x$.
A resolvent family $(S(t))_{t\geq0}$ is called
exponentially bounded, if there exist $M>0$ and $\omega\in\mathbb{R}$
such that $\| S(t)\| \leq Me^{\omega t}$
for all $t\geq0$, and the pair $(M,\omega)$ is called
type of $(S(t))_{t\geq0}$. The growth bound
of $(S(t))_{t\geq0}$ is 
$\omega_0=\inf\{ \omega\in\mathbb{R},\,\| S(t)\| \leq Me^{\omega t},t\geq0,\,
 M>0\} $.
The resolvent family is called exponentially stable if $\omega_0<0$.

Note that, contrary to the case of $\mathcal{C}_0$-semigroup, resolvent
for \eqref{eq:pb original} need not to be exponentially bounded:
a counterexample can be found in \cite{Deschpruss,Pruss93}. However,
there is checkable condition guaranteeing that \eqref{eq:pb original}
possesses an exponentially bounded resolvent operator.

We will use the Laplace transform at times. Suppose 
$g:\mathbb{R}^{+}\to X$
is measurable and there exist $M>0$, $\omega\in\mathbb{R}$, such
that $\| g(t)\| \leq Me^{\omega t}$ for almost $t\geq0$. Then the Laplace transform
\[
\widehat{g}(\lambda)=\int_0^{\infty}e^{-\lambda t}g(t)dt,
\]
exists for all $\lambda\in\mathbb{C}$ with $Re\lambda>\omega$.

A function $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$ is said to be
$\omega$ (resp. $\omega^{+}$)-exponentially bounded if 
$\int_0^{\infty}e^{-\omega s}|a(s)|ds<\infty$
for some $\omega\in\mathbb{R}$ (resp. $\omega>0$).

The following proposition stated in \cite{Pruss93}, establishes the
relation between resolvent family and Laplace transform.

\begin{proposition} \label{prop2.5} 
Let $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$
be $\omega$-exponentially bounded. Then \eqref{eq:pb original} admits
a resolvent family $(S(t))_{t\geq0}$ of type
$(M,\omega)$ if and only if the following conditions hold:
\begin{itemize}
\item [(i)] $\hat{a} (\lambda)\neq0$ and $1/\hat{a}(\lambda)\in\rho(A)$,
for all $\lambda>\omega$.
\item [(ii)] $H(\lambda):=\frac{1}{\lambda\hat{a}(\lambda)}
(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}$
called the resolvent associated with $(S(t))_{t\geq0}$ satisfies
\[
\| H^{(n)}(\lambda)\| \leq Mn! (\lambda-\omega)^{-(n+1)} \quad 
\text{for all $\lambda>\omega$ and $n\in\mathbb{N}$}.
\]
\end{itemize}
\end{proposition}

Under these assumptions the Laplace-transform of $S(\cdot)$
is well-defined and it is given by $\widehat{S}(\lambda)=H(\lambda)$
 for all $\lambda>\omega$.

\section{Domains of $A$: A Review}

Assuming the existence of a resolvent family $(S(t))_{t\geq0}$ for
\eqref{eq:pb original}, it is natural to ask how to characterize
the domain $D(A)$ of the operator $A$ in terms of the resolvent
family. This is important, for instance in order to study the Favard
class in perturbation theory (see. \cite{JUNG1999,Lizama2007}). For
very special case, the answer to the above question is well-known.
For instance, when $a(t)=1$ or $a(t)=t$, $A$ is the generator of
a $\mathcal{C}_0$-semigroup $(\mathbb{T}(t))_{t\geq0}$
or a cosine family $(C(t))_{t\geq0}$ and we have:
\begin{gather*}
D(A)=\big\{ x\in X: \lim_{t\to0^{+}}\frac{\mathbb{T}(t)x-x}{t} 
\text{ exists}\big\}, \\
D(A)=\big\{ x\in X: \lim_{t\to0^{+}}\frac{C(t)x-x}{t^{2}} \text{ exists}\} ,
\end{gather*}
respectively (see. \cite{Pruss93}).

A reasonable formula for the generator of resolvent families and $k$-regularized
resolvent families introduced in \cite{Lizama2000,Lizama2003} have
been established by assuming very mild conditions on the kernels $a(t)$
and $k(t)$. See. \cite[Theorem 2.5]{JUNG1999} and \cite[Theorem 2.1]{Lizama2003}.
It was observed in \cite{JUNG1999} that $D(A)$ has the
following characterization.

\begin{proposition}\label{propjung} 
Let \eqref{eq:pb original} admit a resolvent family
with growth bound $\omega$ (such that the Laplace transform of the
resolvent exists for $\lambda>\omega$) for $\omega$-exponentially
bounded $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$. Set for $0<\theta<\pi/2$
and $\epsilon>0$
\[
\Omega_{\theta}^{\epsilon}
:=\big\{ \frac{1}{\widehat{a}(\lambda)}:  Re\lambda>\omega+\epsilon,\,
|\arg\lambda|\leq\theta\big\} .
\]
Then the following characterization of $D(A)$ holds
\[
D(A)=\big\{ x\in X: \lim_{|\mu|\to\infty,\,
\mu\in\Omega_{\theta}^{0}}\mu A(\mu I-A)^{-1}x\,\text{ exists}\big\} .
\]
\end{proposition}

Without loss of generality we may assume that 
$\int_0^t |a(s)|^pds\neq0$
for all $t>0$ and some $1\leq p<\infty$. Otherwise we would have
for some $t_0>0$ and $p_0\geq1$ that $a(t)=0$ for
almost all $t\in[0,t_0]$, and thus by definition of
resolvent family $S(t)=I$ for $t\in[0,t_0]$.
This implies that $A$ is bounded, which is the trivial case with
$X=D(A)$.

In what follows, we will use in the forthcoming sections the following
assumption on $a\in L_{\rm loc}^p(\mathbb{R}^{+})$ with
$1\leq p<\infty$. It corresponds to \cite[Assumption 2.3]{JUNG1999}
when $p=1$.
\begin{itemize}
\item [(H1)] There exist $\epsilon_{a}>0$ and $t_{a}>0$, such
that for all $0<t\leq t_{a}$, 
\[
|\int_0^t a(s)ds|\geq\epsilon_{a}\int_0^t |a(s)|^pds.
\]
\end{itemize}
This is the case for functions $a$, which are positive 
(resp. $a(I)\subset]0,1]$)
at some interval $I=[0,t_{a}[$ for $p=1$ (resp.  $p>1$).
For almost all reasonable functions in applications it is easy to
see that they satisfy this assumption. There are nonetheless examples
of functions that do not. 


Now let us define the set $\widetilde{D}(A)$ as follows:
\[
\widetilde{D}(A):=\big\{ x\in X: 
\lim_{t\to0^{+}}\frac{S(t)x-x}{(1*a)(t)}\text{  exists}\big\}\,
\]
where $(S(t))_t\ge 0$ is a resolvent familly associated with 
\eqref{eq:pb original}.

It was proved in \cite{JUNG1999} that under (H1),
\begin{equation}
D(A) =  \widetilde{D}(A)=\{x\in X:
\lim_{t\to0^{+}}\frac{S(t)x-x}{(1*a)(t)}=Ax\}.\label{eq:Jung}
\end{equation}
From now and in view of this result we say that the pair $(A,a)$
is a generator of a resolvent family $(S(t))_{t\geq0}$.

\begin{remark} \label{rmk3.2} \rm
When $a=1+1*k$, with $k\in L_{\rm loc}^{1}(\mathbb{R}^{+})$,
the Volterra system \eqref{eq:pb original} with $f(t)=x_0$
is equivalent to the  integrodifferential Volterra system
\begin{equation}
\dot{x}(t)=Ax(t)+\int_0^t k(t-s)Ax(s)ds,\quad  t\geq0.\label{InDiV}
\end{equation}
Furthermore, if \eqref{InDiV} admits a resolvent family $(S(t))_{t\geq0}$,
then it is easy to see that
\end{remark}
\begin{align*}
\widetilde{D}(A) 
& =  \{x\in X: \lim_{t\to0^{+}}\frac{S(t)x-x}{[1*(1+1*k)](t)}=Ax\},\\
& =  \big\{ x\in X: \lim_{t\to0^{+}}\frac{S(t)x-x}{t}=Ax\big\} .
\end{align*}

It is well-known that if $k\in BV_{\rm loc}(\mathbb{R}^{+})$;
(the space of functions locally of bounded variation), then the operator
$A$ becomes a generator of a $\mathcal{C}_0$-semigroup
$(\mathbb{T}(t))_{t\geq0}$,
which is a necessary and sufficient condition for the existence of
a resolvent family (see. \cite{Pruss93}) . Whence $\widetilde{D}(A)$
is also characterized in term of $(\mathbb{T}(t))_{t\geq0}$ and we
have
\[
\widetilde{D}(A)=\big\{ x\in X: { \lim_{t\to0^{+}}}
\frac{\mathbb{T}(t)x-x}{t}=Ax\big\} 
=\big\{ x\in X: \lim_{t\to0^{+}}\frac{S(t)x-x}{t}=Ax\big\} .
\]



\section{Favard spaces with kernel}

In semigroup theory the Favard space sometimes called the generalized
domain is defined for a given semigroup $(\mathbb{T}(t))_{t\geq0}$
(with $A$ as its generator) as
\[
\widetilde{F}^{\alpha}(A)
:=\big\{ x\in X: \sup_{t>0}\frac{\| \mathbb{T}(t)x-x\| }{t^{\alpha}}<\infty\big\} ,
\quad 0<\alpha\leq1,
\]
with norm
\[
\| x\| _{\widetilde{F}^{\alpha}(A)}
:=\| x\| +{ \sup_{t>0}}\frac{\| \mathbb{T}(t)x-x\| }{t^{\alpha}},
\]
 which makes $\widetilde{F}^{\alpha}(A)$ a Banach space.
$\mathbb{T}(t)$ is a bounded operator on $\widetilde{F}^{\alpha}(A)$
but is not necessary strongly continuous on it. $X_1$ is a closed
subspace of $\widetilde{F}^{\alpha}(A)$ and both spaces
coincide when $\alpha=1$, and $X$ is
reflexive (see. e.g., \cite{EngelNagel;2000}). It is natural to ask
how to define in a similar way $\widetilde{F}^{\alpha}(A)$ of the
operator $A$ in terms of the resolvent family. In fact, these spaces
can be defined for general solution families in a similar way. In
fact, it can be defined for all $A$, for which there exists a sequence
$(\lambda_n)_n$ with $\lambda_n\in\rho(A)$ and $|\lambda_n|\to\infty$
in a similar fashion, as was proved in \cite{JUNG1999} for resolvent
family and in \cite{Lizama2007} for integral resolvent family and
in \cite{Lizama2009} for $(a,k)$-resolvent family for the case $\alpha=1$.
Remark that both \cite{JUNG1999} and \cite{Lizama2007} have not
considered the Favard class of order $\alpha$. These spaces will
be the topic of this section and will be useful for the notion of
the admissibility considered in Section 5.

This leads to the following definition which corresponds to a natural
extension, in our context, of the Favard classes frequently used in
approximation theory for semigroups.

\begin{definition} \label{def4.1} \rm
 Let \eqref{eq:pb original} admit a bounded resolvent
family $(S(t))_{t\geq0}$ on $X$, for $\omega^{+}$-exponentially
bounded $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$. For $0<\alpha\leq1$,
we define the ``frequency'' Favard space of order $\alpha$ associated
with $(A,a)$ as follows:
\begin{align*}
F^{\alpha}(A)
&:= \big\{ x\in X: \sup_{\lambda>\omega}\| \lambda^{\alpha-1}
 \frac{1}{\hat{a}(\lambda)}A\big(\frac{1}{\hat{a}
 (\lambda)}I-A\big)^{-1}x\| <\infty\big\} ,\\
 &= \big\{ x\in X: \sup_{\lambda>\omega}
 \| \lambda^{\alpha}AH(\lambda)x\| <\infty\big\} .
\end{align*}
\end{definition}

\begin{remark} \label{rmk4.2} \rm

(i) As for the semigroups it is natural to define the following
space
\[
\widetilde{F}^{\alpha}(A)
:=\big\{ x\in X: \sup_{t>0}\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\alpha}}<\infty\Big\} ,
\]
for $(A,a)$ generator of a resolvent family $(S(t))_{t\geq0}$
on $X$.

(ii) It is clear that $\widetilde{D}(A)\subset\widetilde{F}^{1}(A)$
and by virtue of Proposition \ref{propjung} we have $D(A)\subset F^{1}(A)$.
Moreover, if $a$ satisfies (H1) then $D(A)\subset\widetilde{F}^{1}(A)$
due to the fact that $F^{1}(A)\subset\widetilde{F}^{1}(A)$
(see. \cite{JUNG1999}). In this way, for different functions $a(t)$
we obtain different Favard classes of order $\alpha$ which may be
considered as extrapolation spaces between $D(A)$ and
$X$.

(iii) When $a(t)=1$, we recall that and $(S(t))_{t\geq0}$
corresponds to a bounded $\mathcal{C}_0$-semigroup generated by
$A$. In this situation we obtain 
\[
F^{\alpha}(A)=\big\{ x\in X: { \sup_{\lambda>0}}
\| \lambda^{\alpha}A(\lambda I-A)^{-1}x\| <\infty\big\} 
\]
and $F^{\alpha}(A)=\widetilde{F}^{\alpha}(A)$. This case is well
known, (see. e.g. \cite{EngelNagel;2000}).

(iv) The Favard class of $A$ with kernel $a(t)$ can
be alternatively defined as the subspace of $X$ given by 
$\big\{ x\in X: { \limsup_{\lambda\to\infty}}\| \lambda^{\alpha-1}
\frac{1}{\widehat{a}(\lambda)}A(\frac{1}{\widehat{a}(\lambda)}I-A)^{-1}x\|
 <\infty\big\} $.
As a consequence of $S(t)$ being bounded, the above space coincides
with $F^{\alpha}(A)$ in Definition \ref{def4.1} and that
$\widetilde{F}^{\alpha}(A)
:=\big\{ x\in X: { \sup_{0<t\leq1}}\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\alpha}}
<\infty\big\} $.

(v) Let $a=1+1*k$, with $k\in L_{\rm loc}^{1}(\mathbb{R}^{+})$,
and $(A,a)$ be a generator of a bounded resolvent family
$(S(t))_{t\geq0}$ on $X$. Then, 
$\widetilde{F}^{\alpha}(A)=\big\{ x\in X: { \sup_{0<t\leq1}}
\frac{\| S(t)x-x\| }{t^{\alpha}}<\infty\big\} $
(due to $\lim_{t\to0^{+}}\frac{(1*a)(t)}{t}=1$)
and we have $S(t)F^{\alpha}(A)\subset F^{\alpha}(A)$
for all $\alpha\in]0,1]$ and $t\geq0$ thanks to \cite[Theorem 7]{GrimmerPrus1985}
($(\mu I-A)^{-1}$commutes with $S(t)$ for
all $\mu\in\rho(A)$).
\end{remark}

The proof of the following proposition is immediate.

\begin{proposition}
The Favard classes of order $\alpha$ of $A$ with kernel $a(t)$,
$F^{\alpha}(A)$ and $\widetilde{F}^{\alpha}(A)$
are Banach spaces with respect to the norms
\begin{gather*}
\| x\| _{F^{\alpha}(A)}
:=\| x\| +{ \sup_{\lambda>\omega}}\| \lambda^{\alpha-1}
\frac{1}{\hat{a}(\lambda)}A(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}x\| , \\
\| x\| _{\widetilde{F}^{\alpha}(A)}
:=\| x\| +{ \sup_{0<t\leq1}}\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\alpha}},
\end{gather*}
respectively.
\end{proposition}

As for the semigroups case, we obtain the natural inclusions between
the Favard class  for different exponents.

\begin{proposition}\label{prop3.3} 
Let \eqref{eq:pb original} admit a bounded resolvent
family $(S(t))_{t\geq0}$ on $X$ for $\omega^{+}$-exponentially
bounded $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$. For all $0<\beta<\alpha\leq1$,
we have:
\begin{itemize}
\item [(i)] $D(A)\subset F^{\alpha}(A)\subset F^{\beta}(A)$.
\item [(ii)] $\widetilde{D}(A)\subset\widetilde{F}^{\alpha}(A)
\subset\widetilde{F}^{\beta}(A)$.
\end{itemize}
\end{proposition}

\begin{proof}
(i) Let $x\in F^{\alpha}(A)$, then for all $\lambda>\omega$,
we have
\begin{align*}
\| \lambda^{\beta-1}\frac{1}{\hat{a}(\lambda)}A(\frac{1}{\hat{a}
(\lambda)}I-A)^{-1}x\| 
 &= \| \lambda^{\beta-\alpha}\lambda^{\alpha-1}
 \frac{1}{\hat{a}(\lambda)}A(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}x\| \\
 &= \lambda^{\beta-\alpha}\| \lambda^{\alpha-1}
 \frac{1}{\hat{a}(\lambda)}A(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}x\| \\
 & \leq  \frac{1}{\lambda^{\alpha-\beta}}
 \sup_{\lambda>\omega}\| \lambda^{\alpha-1}\frac{1}{\hat{a}(\lambda)}
 A(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}x\| \\
 & \leq  \frac{1}{\omega{}^{\alpha-\beta}}
 \sup_{\lambda>\omega}\| \lambda^{\alpha-1}
\frac{1}{\hat{a}(\lambda)}A(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}x\| ,
\end{align*}
 which implies that $x\in F^{\beta}(A)$ and from Remark
\ref{rmk4.2} (ii) we deduce that $D(A)\subset F^{\alpha}(A)$.

(ii) Let $x\in\widetilde{F}^{\alpha}(A)$, and $0<t\leq1$.
We have
\begin{align*}
\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\beta}}
 &= \frac{1}{|\int_0^t a(s)ds|^{\beta-\alpha}}
 \frac{\| S(t)x-x\| }{|\int_0^t a(s)ds|^{\alpha}}\\
 & \leq  \| a\| _{L^{1}[0,1]}^{\alpha-\beta}
 \sup_{0<t\leq1}\frac{\| S(t)x-x\| }{|\int_0^t a(s)ds|^{\alpha}}
\end{align*}
 Hence $x\in\widetilde{F}^{\beta}(A)$ and that 
$\widetilde{D}(A)\subset\widetilde{F}^{\alpha}(A)$
due to Remark \ref{rmk4.2} (ii).
\end{proof}

 Note that under (H1) we have:
 (i) $F^{1}(A)\subset\widetilde{F}^{1}(A)$
(see. \cite[Assumption 2.3]{JUNG1999}). Whereas the inclusion (ii)
$\widetilde{F}^{1}(A)\subset F^{1}(A)$ was
proved under a strong assumption in \cite[Assumption 3.1]{JUNG1999}.
Now we  prove that (ii) holds for all non negative 
$a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$.

\begin{proposition} \label{prop12} 
Let \eqref{eq:pb original} admit a bounded resolvent
family $(S(t))_{t\geq0}$ on $X$, for $\omega^{+}$-exponentially
bounded non negative $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$.
Then, we have $F^{1}(A)=\widetilde{F}^{1}(A)$.
\end{proposition}

\begin{proof}
Since $a(t)$ is a non negative, (H1) is satisfied
and by \cite{JUNG1999} we have $F^{1}(A)\subset\widetilde{F}^{1}(A)$.
Now let $x\in\widetilde{F}^{1}(A)$ and set 
${ \sup_{0<t\leq1}}\frac{\| S(t)x-x\| }{(1*a)(t)}:=J_{x}<\infty$.
We write 
\[
\frac{1}{\hat{a}(\lambda)}A(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}
=\lambda AH(\lambda),
\]
for all $\lambda>\omega$. Using the integral representation of the
resolvent (see. Proposition \ref{prop2.5}) we obtain:
\begin{align*}
\lambda AH(\lambda)x 
&= \frac{\lambda}{\widehat{a}(\lambda)}H(\lambda)x-\frac{1}{\widehat{a}(\lambda)}x\\
 &= \frac{\lambda}{\widehat{a}(\lambda)}[H(\lambda)x-\frac{1}{\lambda}x]\\
 &= \frac{\lambda}{\widehat{a}(\lambda)}\int_0^{\infty}e^{-\lambda s}(S(s)x-x)ds\\
 &= \frac{\lambda}{\widehat{a}(\lambda)}\int_0^{\infty}e^{-\lambda s}(1*a)(s)
\frac{S(s)x-x}{(1*a)(s)}ds.
\end{align*}
The resolvent family $(S(t))_{t\geq0}$ being bounded;
$\| S(t)\| \leq M$ for some $M>0$ and all $t\geq0$.
Then we obtain
\begin{align*}
\| \lambda AH(\lambda)x\|  
&\leq  \frac{\lambda}{\widehat{a}(\lambda)}
 \int_0^{\infty}e^{-\lambda s}(1*a)(s)ds.\sup_{t>0}
 \frac{\| S(t)x-x\| }{(1*a)(t)}\\
 &\leq  \frac{\lambda}{\widehat{a}(\lambda)}\int_0^{\infty}
 e^{-\lambda s}(1*a)(s)ds.(L\| x\| +\sup_{0<t\leq1}\frac{\| S(t)x-x\| }{(1*a)(t)})\\
 &= \frac{\lambda}{\widehat{a}(\lambda)}\widehat{1*a}(\lambda).(L\| x\| +J_{x})\\
 &= L\| x\| +J_{x},
\end{align*}
with $L=\frac{1+M}{(1*a)(1)}$. This implies
that ${ \sup_{\lambda>\omega}}\| \lambda AH(\lambda)x\| <\infty$,
which completes the proof.
\end{proof}

Note that in the semigroup case, i.e. $a(t)=1$, we have the well-known
result that $\widetilde{F}^{\alpha}(A)$=$F^{\alpha}(A)$,
(see. e.g. \cite{EngelNagel;2000}). In what follows, we investigate
conditions on the kernel $a$ to prove that this is the case for the
$(A,a)$ generator of the resolvent families.
Note that for all $\omega^{+}$-exponentially bounded function $a$,
it is clear that $(1*a)^{\alpha}$ is also $\omega^{+}$-exponentially
bounded (due to $x^{\alpha}\leq1+x$ for all $x\geq0$ and $\alpha\in]0,1]$).

We consider the following assumption on $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$
and $0<\alpha\leq1$.
\begin{itemize}
\item [(H2)] $a$ is $\omega^{+}$-exponentially
bounded and there exists $\epsilon_{a,\alpha}>0$, such that for all
$\lambda>\omega$
\[
|\hat{a}(\lambda)|\geq\epsilon_{a,\alpha}
\lambda^{\alpha}\int_0^{\infty}e^{-\lambda t}|(1*a)(t)|^{\alpha}dt.
\]
\end{itemize}
Note that conditions (H2) and $\lambda\hat{a}(\lambda)$
being bounded, are independent (see. e.g. Example \ref{example4.7} (ii)).

\begin{example} \label{example4.7}\rm
(i) The famous case $a(t)=1$ satisfies the condition (H2)
for all $\alpha\geq0$ due to
\[
\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}
\int_0^{\infty}e^{-\lambda t}((1*1)(t))^{\alpha}dt
=\Gamma(\alpha+1)\quad\text{for all $\lambda>0$},
\]
which corresponds to the semigroup case.

(ii) Consider the standard kernel $a(t)=t^{\beta-1}/\Gamma(\beta)$
for $\beta\in[0,1[$. $a$ is non negative and for all $\lambda>0$
\begin{align*}
\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}
\int_0^{\infty}e^{-\lambda t}((1*a)(t))^{\alpha}dt
&= \frac{\lambda^{\alpha+\beta-\alpha\beta-1}}{\beta^{\alpha}
(\Gamma(\beta))^{\beta}\Gamma(\alpha\beta+1)},\\
 &= \frac{\lambda^{(\alpha-1) (1-\beta)}}{\beta^{\alpha}
(\Gamma(\beta))^{\beta}\Gamma(\alpha\beta+1)}.
\end{align*}
 Thus $a$ satisfies (H2) and $\lambda\hat{a}(\lambda)=\lambda^{1-\beta}$
is not bounded for $\beta\in[0,1[$.

(iii) Let $a(t)=\mu+\nu t^{\beta}$, $0<\beta<1$, $\mu>0$, $\nu>0$.
Then we have $\widehat{a}(\lambda)=\frac{\mu}{\lambda}
+\frac{\nu}{\lambda^{\beta+1}}\Gamma(\beta+1)$
for $\lambda>0$ and $(1*a)(t)=\mu t+\nu\frac{t^{\beta+1}}{\beta+1}$.
Further, for $\alpha\in]0,1]$ we have
\begin{align*}
&\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}\int_0^{\infty}
e^{-\lambda t}((1*a)(t))^{\alpha}dt \\
&= \frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}
 \int_0^{\infty}e^{-\lambda t}(\mu t+\nu\frac{t^{\beta+1}}{\beta+1})^{\alpha}dt,\\
&= \frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}\int_0^{1}
 e^{-\lambda t}(\mu t+\nu\frac{t^{\beta+1}}{\beta+1})^{\alpha}dt
 +\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}\int_1^{\infty}e^{-\lambda t}
 (\mu t+\nu\frac{t^{\beta+1}}{\beta+1})^{\alpha}dt,\\
&\leq  (\mu+\frac{\nu}{\beta+1})^{\alpha}\frac{\Gamma(\alpha+1)}{\mu}
+(\mu+\frac{\nu}{\beta+1})^{\alpha}\frac{\Gamma(\alpha\beta+\alpha+1)}{\mu}
 \lambda^{-\alpha\beta}.
\end{align*}
Then (H2) is satisfied. Note that for $\beta=1$,
$a(t)=\mu+\nu t$, Equqation \eqref{eq:pb original} corresponds
to the model of a solid of Kelvin-Voigt (see. \cite{Pruss93}).

(iv) Let $a=1+1*k$ with $k(t)=e^{-t}$. We have 
$\widehat{a}(\lambda)=\frac{\lambda+2}{\lambda(\lambda+1)}$
for all $\lambda>0$ and $(1*a)(t)=2t+e^{-t}-1\leq2t$
for all $t\geq0$. Hence
\[
\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}\int_0^{\infty}
e^{-\lambda t}((1*a)(t))^{\alpha}dt 
\leq  \frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}
\int_0^{\infty}e^{-\lambda t}(2t)^{\alpha}dt,\\
= \frac{\lambda+1}{\lambda+2}\cdot2^{\alpha} \Gamma(\alpha+1).
\]
Then $a$ satisfies (H2).

(v) Let $a=1+1*k$ with $k(t)=-e^{-t}$. We have 
$\widehat{a}(\lambda)=\frac{1}{\lambda+1}$
for all $\lambda>0$ and that $(1*a)(t)=1-e^{-t}\leq t$
for all $t\geq0$. Hence
\[
\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}
\int_0^{\infty}e^{-\lambda t}((1*a)(t))^{\alpha}dt
\leq  \lambda^{\alpha}(\lambda+1)\int_0^{\infty}e^{-\lambda t}t{}^{\alpha}dt
= \frac{\lambda+1}{\lambda} \Gamma(\alpha).
\]
Then $a$ satisfies (H2).
\end{example}

The following result establishes the relation between the spaces 
$\widetilde{F}^{\alpha}(A)$
and $F^{\alpha}(A)$ and therefore generalizes 
\cite[Proposition 5.12]{EngelNagel;2000}.

\begin{proposition} \label{prop13} 
Let \eqref{eq:pb original} admit a bounded resolvent
family $(S(t))_{t\geq0}$ on $X$, for $\omega^{+}$-exponentially
bounded $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$ and $0<\alpha\leq1$.
\begin{itemize}
\item [(i)] If $a$ satisfies (H1) and $\lambda\widehat{a}(\lambda)$
is bounded for $\lambda>\omega$, then 
$F^{\alpha}(A)\subset\widetilde{F}^{\alpha}(A)$.

\item [(ii)] If $a$ is non negative satisfying (H2),
then $\widetilde{F}^{\alpha}(A)\subset F^{\alpha}(A)$.
\end{itemize}
\end{proposition}

\begin{proof}
(i) Let $x\in F^{\alpha}(A)$ and $0<t\leq1$. Then
${ \sup_{\lambda>\omega}}\| \lambda^{\alpha}AH(\lambda)x\| =:K_{x}<\infty$.
Using the integral representation of the resolvent (see. Proposition
\ref{prop2.5}), we obtain
\[
x = \lambda H(\lambda)x-\lambda\widehat{a}(\lambda)AH(\lambda)x
\text{ for }\lambda>\omega,
=:  x_{\lambda}-y_{\lambda}.
\]
 Since $x_{\lambda}\in D(A)$ and using (S2)-(S3) we have
\begin{align*}
\| S(t)x_{\lambda}-x_{\lambda}\|  
&= \| \int_0^t a(t-s)S(s)Ax_{\lambda}ds\| \\
 &\leq  \int_0^t |a(t-s)|\cdot\| S(s)\| \cdot\| Ax_{\lambda}\| ds\\
 &\leq  M \| Ax_{\lambda}\| \int_0^t |a(s)|ds\\
 &= M\| \lambda^{\alpha}AH(\lambda)x\| \lambda^{1-\alpha} (1*|a|)(t)\\
 &\leq  MK_{x} \lambda^{1-\alpha} (1*|a|)(t).
\end{align*}
On the other hand, $(S(t))_{t\geq0}$ is bounded
by $M$ and we have
\begin{align*}
\| S(t)y_{\lambda}-y_{\lambda}\|  
&\leq  \| S(t)y_{\lambda}\| +\| y_{\lambda}\| \\
 &\leq  \| S(t)\| \,\| y_{\lambda}\| +\| y_{\lambda}\| \\
 &\leq  (M+1)\| y_{\lambda}\| \\
 &= (M+1)\| \lambda\widehat{a}(\lambda)AH(\lambda)x\| \\
 &= (M+1)|\widehat{a}(\lambda)|\,\| \lambda^{\alpha}AH(\lambda)x\| 
 \lambda^{1-\alpha}\\
 &\leq  (M+1)K_{x}|\widehat{a}(\lambda)|\lambda^{1-\alpha}.
\end{align*}
This implies
\begin{align*}
&\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\alpha}} \\
&\leq  \frac{MK_{x}\lambda^{1-\alpha}(1*|a|)(t)}{|(1*a)(t)
|^{\alpha}}+\frac{(M+1)K_{x}.|\widehat{a}(\lambda)|
\lambda^{1-\alpha}}{|(1*a)(t)|^{\alpha}}\\
 &\leq  \frac{MK_{x}}{\epsilon_{a}^{\alpha}}
\lambda^{1-\alpha}((1*|a|)(t))^{1-\alpha}
 +\frac{(M+1)K_{x}}{\epsilon_{a}^{\alpha}}
 |\lambda\widehat{a}(\lambda)|.\lambda^{-\alpha}((1*|a|)(t))^{-\alpha}\\
 &\leq  \frac{MK_{x}}{\epsilon_{a}^{\alpha}}
\lambda^{1-\alpha}((1*|a|)(t))^{1-\alpha}+\frac{(M+1)K_{x}K'}{\epsilon_{a}^{\alpha}}
\lambda^{-\alpha}((1*|a|)(t))^{-\alpha}.
\end{align*}
The third inequality is realized under (H1): 
$|(1*a)(t)|\geq\epsilon_{a}(1*|a|)(t)$
and that $|\lambda\widehat{a}(\lambda)|\leq K'$
for some $K'>0$ and for $\lambda$ large enough. Substituting
$\lambda_{t}=\frac{N_{\omega}}{(1*|a|)(t)}>\omega$
for $t\in]0,1]$ ($\lambda_{t}\to\infty$ as $t\to0)$
with $N_{\omega}=1+\omega(1*|a|)(1)$,
we obtain
\[
\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\alpha}} 
\leq  \frac{MK_{x}N_{\omega}^{1-\alpha}}{\epsilon_{a}^{\alpha}}
+\frac{(M+1)K_{x}K'N_{\omega}^{-\alpha}}{\epsilon_{a}^{\alpha}},
\]
for all $0<t\leq1$. Thus
${\sup_{0<t\leq1}}\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\alpha}}<\infty$,
and hence $x\in\widetilde{F}^{\alpha}(A)$.

(ii) Let $x\in\widetilde{F}^{\alpha}(A)$ be given,
then ${ \sup_{0<t\leq1}}\frac{\| S(t)x-x\| }{|(1*a)(t)|^{\alpha}}:=J_{x}<\infty$.
For $\lambda>\omega$ we write 
$\lambda H(\lambda)x-x=\lambda\widehat{a}(\lambda)AH(\lambda)x$
then
\[
\lambda AH(\lambda)x 
= \frac{\lambda}{\widehat{a}(\lambda)}(H(\lambda)x-\frac{1}{\lambda}x)
= \frac{\lambda}{\widehat{a}(\lambda)}\int_0^{\infty}e^{-\lambda t}(S(t)x-x)dt,
\]
and
\[
\lambda^{\alpha}AH(\lambda)x
=\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}\int_0^{\infty}
e^{-\lambda t}(1*a)^{\alpha}(t)(\frac{S(t)x-x}{(1*a)^{\alpha}(t)})dt,
\]
 The fact that $a$ is non negative and satisfies (H2), implies
\[
\| \lambda^{\alpha}AH(\lambda)x\|  
\leq  \frac{(L_{\alpha}\| x\| +J_{x})}{\epsilon_{a,\alpha}}\quad
\text{with } L_{\alpha}=\frac{1+M}{(1*a)^{\alpha}(1)}.
\]
Therefore, ${ \sup_{\lambda>\omega}}\| \lambda^{\alpha}AH(\lambda)x\| <\infty$
which completes the proof.
\end{proof}

\begin{remark} \label{rmk4.8} \rm
Let $\alpha\in]0,1]$.

(i) $a(t)=1$. Then $\lambda\widehat{a}(\lambda)$
is bounded for all $\lambda>0$ and $a$ satisfies (H1).
Furthermore $a$ satisfies (H2) (see. Example
\ref{example4.7} (i)) and by virtue of Proposition \ref{prop13},
we obtain $F^{\alpha}(A)=\widetilde{F}^{\alpha}(A)$.
Hence we recover a result for $\mathcal{C}_0$-semigroups case which
corresponds to \cite[Proposition 5.12]{EngelNagel;2000}.

(ii) $a(t)=t$ satisfies (H1) and we have 
$\lambda\widehat{a}(\lambda)=\frac{1}{\lambda}$
is bounded for all $\lambda>\omega>0$ . By virtue of Proposition \ref{prop13}
(i) we obtain $F^{\alpha}(A)\subset\widetilde{F}^{\alpha}(A)$.

(iii) Let $a$ be a completely positive function. Then (see. \cite{Pruss93})
$a$ is non negative and 
\[
\lambda\widehat{a}(\lambda)
=\frac{1}{k_0+\frac{1}{k_{\infty}}+\widehat{k_1}(\lambda)},
\]
for all $\lambda>0$ where $k_0\geq0,\, k_{\infty}\geq0$ and $k_1$
is non negative decreasing function tending to $0$ as $t\to\infty$.
That is $\lambda\widehat{a}(\lambda)$ is bounded and by
Proposition \ref{prop13} (i) we obtain 
$F^{\alpha}(A)\subset\widetilde{F}^{\alpha}(A)$.

(iv) Consider the standard kernel $a(t)=\frac{t^{\beta-1}}{\Gamma(\beta)}$,
with $\beta\in[1,2[$. Then $a$ satisfies (H1) and that 
$\lambda\widehat{a}(\lambda)=\lambda\cdot\lambda^{-\beta}=\lambda^{1-\beta}$,
for all $\lambda>\omega>0$ is bounded, thus from Proposition \ref{prop13}
(i) $F^{\alpha}(A)\subset\widetilde{F}^{\alpha}(A)$.

(v) Let $a(t)=\frac{t^{\beta-1}}{\Gamma(\beta)}$,
with $\beta\in[0,1[$. Then $a$ is non negative and we have
\begin{align*}
\frac{\lambda^{\alpha}}{\widehat{a}(\lambda)}
\int_0^{\infty}e^{-\lambda t}((1*a)(t))^{\alpha}dt
&= \frac{\lambda^{\alpha+\beta-\alpha\beta-1}}{\beta^{\alpha}
(\Gamma(\beta))^{\beta} \Gamma(\alpha\beta+1)}\\
 &= \frac{\lambda^{(\alpha-1) (1-\beta)}}{\beta^{\alpha}
(\Gamma(\beta))^{\beta} \Gamma(\alpha\beta+1)}
\end{align*}
which is bounded, for all $\lambda>\omega>0$ due to $\beta\in[0,1[$. This
implies that $a$ satisfies (H2) and according to Proposition
\ref{prop13} (ii) we can conclude that 
$\widetilde{F}^{\alpha}(A)\subset F^{\alpha}(A)$.

(vi) Let $a(t)=\mu+\nu t^{\beta}$, $0<\beta<1$, $\mu>0$, $\nu>0$.
By Proposition \ref{prop13} we have 
$\widetilde{F}^{\alpha}(A)=F^{\alpha}(A)$
according to the Example \ref{example4.7} (iii).

(vii) Let $a=1+1*k$, with $k(t)=\pm e^{-t}$. Proposition
\ref{prop13} yields $\widetilde{F}^{\alpha}(A)=F^{\alpha}(A)$
according to the Example \ref{example4.7} (iv)-(v). In general, for
$k\in L_{\rm loc}^{1}(\mathbb{R}^{+})$, $\omega^{+}$-exponentially bounded,
we have $\lambda\hat{a}(\lambda) =1+\widehat{k}(\lambda)$
which is is bounded for all $\lambda>0$, according to the Riemann-Lebesgue
Lemma. If in addition $a$ satisfies (H1), Proposition \ref{prop13}
(i) asserts that $F^{\alpha}(A)\subset\widetilde{F}^{\alpha}(A)$.
Now, if $k(t)$ is negative with $\widehat{k}(0)\geq-1$
then we obtain a non negative kernel $a$ satisfying $0\leq(1*a)(t)\leq t$.
Hence, both (H1) and (H2)
are satisfied (see. Example \ref{example4.7} (iv)) and using Proposition
\ref{prop13} we obtain $\widetilde{F}^{\alpha}(A)=F^{\alpha}(A)$.
\end{remark}

\begin{definition} \label{def4.9} \rm
A scalar function $a:]0,\infty[\to\mathbb{R}$
is called creep if it is continuous, non-negative, non-decreasing
and concave.
\end{definition}

According to \cite[Definition 4.4]{Pruss93}, a creep function has
the  standard form
\[
a(t)=a_0+a_{\infty}t+\int_0^t a_1(\tau)d\tau,
\]
where $a_0=a(0^{+})\geq0,\, a_{\infty}={ \lim_{t\to\infty}}\frac{a(t)}{t}$
and $a_1(t)=\dot{a}(t)-a_{\infty}$ is non
negative, non increasing and ${ \lim_{t\to\infty}}a_1(t)=0$.

The concept of creep function is well known in viscoelasticity theory
and corresponds to a class of functions which are normally verified
in practical situations. We refer to the monograph of Pr\"uss \cite{Pruss93}
for further information.

We finish this section by proving an analogue version to a well-known
result for semigroups in \cite[Theorem 9]{DeschSchappacher;1989}
for resolvent family. We remark that a similar result was proved for
integral resolvent families in \cite{Lizama2007}. For the sake of
completeness we give here the details of the proof.


\begin{lemma} \label{thm22}
 Assume that $(A,a)$ generates a bounded
resolvent family $(S(t))_{t\geq0}$, and $a$ is a creep
function with $a(0^{+})>0$. Then {\small{}for all
 $\xi\in L_{\rm loc}^{1}(\mathbb{R}^{+},\widetilde{F}^{1}(A))$}
and $t>0$, we have $\int_0^t S(t-s)\xi(s)ds\in D(A)$,
and there exists $N>0$ such that
\[
\| A\int_0^t S(t-s)\xi(s)ds\| _{X}
\leq N\int_0^t \| \xi(s)\| _{\widetilde{F}^{1}(A)}ds\quad\text{for all }t>0.
\]
\end{lemma}

\begin{proof}
We  give the proof in three steps. 
Let $t>0$ and $\xi\in L^{1}([0,t],\widetilde{F}^{1}(A))$,
there exists $\xi_n\in\mathcal{C}^{2}([0,t],\widetilde{F}^{1}(A))$,
such that $\xi_n\to\xi$ in $L^{1}([0,t],\widetilde{F}^{1}(A))$ as
$n\to\infty$.
\smallskip

\noindent\textbf{Step 1.} For all $t\geq0$,
$\int_0^t S(t-s)\xi_n(s)ds\in D(A)$.
In fact, let $\varphi_n(s)=\xi_n(s)-\xi_n(0)-s\xi_n'(s)$.
Then $\varphi_n(0)=0$, and $\varphi_n'(0)=0$.
Define $i(s)=s$ and observe that
 $\xi_n(s)=(i*\varphi_n^{''})(s)+\xi_n'(0)i(s)+\xi_n(0)$,
for all $s\in[0,t]$. Since $a$ is a creep function, there
exists a scalar function $b$ such that $a*b=i$, see. 
\cite[Proposition 4.4]{Pruss93}.
Hence, we obtain
\begin{align*}
\int_0^t S(t-s)\xi_n(s)ds 
&= (S*\xi_n)(t)\\
&= (a*S*b*\varphi_n^{''})(t)+(a*S*b)(t)\xi_n'(0)+\int_0^t S(s)\xi_n(0)ds.
\end{align*}

Since $a$ is a creep function with $a(0^{+})>0$, it is easy to see
that the resolvent family $(S(t))_{t\geq0}$ is a solution
of an integrodifferential Volterra equation of the form \eqref{InDiV}.
Thus $\int_0^t S(s)\xi_n(0)ds\in D(A)$,
(see \cite[Lemma 1]{GrimmerPrus1985} and \cite{A.Fadili14}) 
and that $\mathcal{R}((a*S)(t))\subset D(A)$,
we obtain $\int_0^t S(t-s)\xi_n(s)ds\in D(A)$
for all $t\geq0$.
\smallskip

\noindent\textbf{Step 2.} $\int_0^t S(t-s)\xi_n(s)ds\to\int_0^t S(t-s)\xi(s)ds$
as $n\to\infty$ for all $t\geq0$. In fact, by hypothesis
there exists $M>0$ such that $\| S(t)\| \leq M$
for all $t\geq0$, hence
\begin{align*}
\| \int_0^t S(t-s)[\xi_n(s)-\xi(s)]ds\| 
 &\leq  \int_0^t \| S(t-s)\| \,\| \xi_n(s)-\xi(s)\| ds\\
 &\leq  M\int_0^t \| \xi_n(s)-\xi(s)\| _{\widetilde{F}^{1}(A)}ds,
\end{align*}
which tends to zero as $n\to\infty$.
\smallskip

\noindent\textbf{Step 3.} $\int_0^t S(t-s)\xi(s)ds\in D(A)$
for all $t\geq0$. In fact, let $\epsilon>0$ be given.
 Since $\int_0^t S(t-s)\xi_n(s)ds\in D(A)$
(see. step1) and $a$ is non negative, \eqref{eq:Jung}
implies that there exists $\delta>0$, such that for all $0\leq h\leq\delta$
we have
\[
\| \frac{S(h)-I}{(1*a)(h)}\int_0^t S(t-s)\xi_n(s)ds
-A\int_0^t S(t-s)\xi_n(s)ds\| <\epsilon,
\]
equivalently,
\[
\| \int_0^t S(t-s)\frac{S(h)-I}{(1*a)(h)}\xi_n(s)ds-A\int_0^t S(t-s)\xi_n(s)ds\|
 <\epsilon.
\]
Using that $\xi_n(\cdot)\in\widetilde{F}^{1}(A)$
and the boundedness of $(S(t))_{t\geq0}$ we obtain
\begin{align*}
\| A\int_0^t S(t-s)\xi_n(s)ds\|  
&\leq  \| \frac{S(h)-I}{(1*a)(h)}\int_0^t S(t-s)\xi_n(s)ds
-A\int_0^t S(t-s)\xi_n(s)ds\| \\
 &\quad+\int_0^t \| S(t-s)\| \sup_{0<h\leq1}\| \frac{S(h)-I}{(1*a)(h)}\xi_n(s)\| ds\\
 &\leq  \epsilon+M\int_0^t \| \xi_n(s)\| _{\widetilde{F}^{1}(A)}ds,
\end{align*}
for all $\epsilon>0$, which implies that
\begin{equation}
\| A\int_0^t S(t-s)\xi_n(s)ds\| 
\leq M\int_0^t \| \xi_n(s)\| _{\widetilde{F}^{1}(A)}ds.\label{InegClaim3}
\end{equation}
Now let $x_n:=\int_0^t S(t-s)\xi_n(s)ds$,
then by step 1 we have $x_n\in D(A)$ and
by step 2, $x_n\to x:=\int_0^t S(t-s)\xi(s)ds$
as $n\to\infty$ for all $t>0$. Moreover by \eqref{InegClaim3}
we have
\begin{align*}
\| Ax_{m}-Ax_n\|  
&= \| A\int_0^t S(t-s)[\xi_{m}(s)-\xi_n(s)]ds\| \\
&\leq  M\int_0^t \| \xi_{m}(s)-\xi_n(s)\| _{\widetilde{F}^{1}(A)}ds\to0,
\end{align*}
as $m,n\to\infty$. This proves that the sequence $(Ax_n)_n$
is Cauchy, and hence $(Ax_n)_n$ converges in $X$,
say $Ax_n\to y\in X$.

Since $A$ is closed, we conclude that $x\in D(A)$ proving
the step 3. Moreover, from \eqref{InegClaim3} we deduce
that 
\[
\| A\int_0^t S(t-s)\xi(s)ds\| \leq M\int_0^t \| \xi(s)\| _{\widetilde{F}^{1}(A)}ds
\]
for all $t>0$ which completes the proof.
\end{proof}

\section{Sufficient and necessary conditions for admissibility}

In this section we go back to the admissibility. We give sufficient
and necessary conditions in terms of the Favard classes introduced
in the above section for the $L^p$-admissibility of control operators
for Volterra systems of the form
\begin{equation}
\begin{gathered}
x(t)=x_0+\int_0^t a(t-s)Ax(s)ds+\int_0^t Bu(s)ds,\quad  t\geq0\\
x(0)=x_0\in X
\end{gathered}\label{eq:pb2}
\end{equation}
Here $A$ is a closed densely defined operator on a Banach space and
$U$ is another Banach space. It is further assumed that the uncontrolled
system (i.e. \eqref{eq:pb2} with $B=0$)
\begin{equation}
x(t)=x_0+\int_0^t a(t-s)Ax(s)ds,\quad  t\geq0,\label{uncontrolled}
\end{equation}
admits a resolvent family $(S(t))_{t\geq0}$.

Since the resolvent of \eqref{uncontrolled} commutes with the operator
$A$, then it can be easily seen that the restriction $(S_1(t))_{t\geq0}$
to $X_1$ of $(S(t))_{t\geq0}$, the solution
of \eqref{uncontrolled}, is strongly continuous. 
Moreover, if $\rho(A)\neq\emptyset$
(in particular if $(S(t))_{t\geq0}$ is exponentially bounded;
see. Proposition \ref{prop2.5}) $(S_1(t))_{t\geq0}$
solves \eqref{uncontrolled} for each $x_0\in X$ and $A_1$ replacing
$A$ . Likewise, $S(t)$ has a unique bounded extension
to $X_{-1}$ for each $t\geq0$ and $t\longmapsto S_{-1}(t)$
is also strongly continuous, and it solves \eqref{uncontrolled} in
$X_{-1}$ with $A_{-1}$ replacing $A$.

If $\rho(A)\neq\emptyset$ and $B\in\mathcal{L}(U,X_{-1})$,
then the mild solution of $\eqref{eq:pb2}$ is formally
given by the variation of constant formula
\begin{equation}
x(t)=S(t)x_0+\int_0^t S_{-1}(t-s)Bu(s)ds,\label{EQU3.2}
\end{equation}
which is actually the classical solution if $B\in\mathcal{L}(U,X)$
and $x_0\in D(A)$ and $u$ sufficiently smooth. In general however,
$B$ is not a bounded operator from $U$ into $X$ and so an additional
assumption on $B$ will be needed to ensure that $x(t)\in X$ for
every $x_0\in X$ and every $u\in L^p([0,\infty[;U)$ or
$L_{\rm loc}^p([0,\infty[;U)$.

In the same spirit of semigroups, the following are the most natural
definitions of the $L^p$-admissibility for resolvent families.

\begin{definition} \label{def5.1} \rm
Let $p\in[1,\infty[$ and $B\in\mathcal{L}(U,X_{-1})$ and assume
that $(S(t))_{t\geq0}$ is exponentially bounded .

(i)  $B$ is called infinite-time $L^p$-admissible
operator for $(S(t))_{t\geq0}$, if there exists a constant
$M>0$ such that
\[
\| S_{-1}*Bu(t)\| \leq M\| u\| _{L^p([0,\infty[,U)}\quad
\text{for all  $u\in L^p([0,\infty[,U)$ and $t>0$.}
\]

(ii)  $B$ is called finite-time $L^p$-admissible operator
for $(S(t))_{t\geq0}$ if there exists $t_0>0$
and a constant $M(t_0)>0$ such that:
\[
\| S_{-1}*Bu(t_0)\| \leq M(t_0)\| u\| _{L^p([0,t_0],U)}\quad
\text{for all  $u\in L^p([0,t_0],U)$}.
\]

(iii) $B$ is called uniformly finite-time $L^p$-admissible
operator for $(S(t))_{t\geq0}$ if for all $t>0$, there exists
a constant $M(t)>0$ such that
\[
\| S_{-1}*Bu(t)\| \leq M(t)\| u\| _{L^p([0,t],U)}
\]
for all $u\in L^p([0,t],U)$ with $\limsup_{t\to 0^{+}} M(t)<\infty$.

For $p\in [1,\infty[$,  we denote by $\mathcal{A}_{\infty}^p(U,X)$, 
$\mathcal{A}^p(U,X)$ and $\mathcal{A}_{u}^p(U,X)$, the space of the infinite-time,
the finite-time and the uniformly finite-time $L^p$-admissible
operators for $(S(t))_{t\geq0}$,
respectively.
\end{definition}

Recall that the condition $\limsup_{t\to0^{+}} M(t)<\infty$
is always satisfied for semigroups (see. \cite{G.Weiss;1989a}). We
prove in Proposition \ref{Equi} (i), that this the case; in particular
if $X$ is reflexive. Note that  the definition of infinite-time
$L^p$-admissible control operator for $(S(t))_{t\geq0}$
was introduced in \cite{Jacob2004b} when $p=2$ and implies the finite-time
$L^{2}$-admissibility condition considered by \cite{JUN2000}. Our
definitions of finite-time and uniformly finite-time $L^p$-admissible
control operator for $(S(t))_{t\geq0}$ correspond to
that of the semigroups, also imply that of \cite{JUN2000} when $p=2$.
Furthermore, it is well-known that:
\begin{itemize}
\item[(P1)] the finite-time $L^p$-admissibility and the uniform finite-time
$L^p$-admissibility are equivalent for semigroups and 

\item[(P2)] the finite-time $L^p$-admissibility and the infinite-time 
$L^p$-admissibility are equivalent for exponentially stable semigroups 
(i.e. $a(t)=1$) for all $p\in[1,\infty[$. 
\end{itemize}
One question that remains open to our
knowledge, is whether for Volterra systems, these problems
(i.e. (P1)--(P2)) are still true for resolvent families. In
the end of this section we give a partial response to these problems
when $p=1$. 


\begin{claim}\label{Haak09} 
Let \eqref{uncontrolled} admit an exponentially stable
resolvent family $(S(t))_{t\geq0}$ and $p\in[1,\infty[$.
The following is a necessary condition for infinite-time $L^p$-admissibility
of control operator $B\in\mathcal{L}(U,X_{-1})$: there exists $L_{p}>0$
such that
\begin{equation}
\| \frac{1}{\lambda\hat{a}(\lambda)}(\frac{1}{\hat{a}
(\lambda)}I-A_{-1})^{-1}B\| _{\mathcal{L}(U,X)}
<\frac{L_{p}}{(Re\lambda)^{1/p}},\label{CN}
\end{equation}
 for all $Re\lambda>0$.
\end{claim}

\begin{proof}
Thanks to Proposition \ref{prop2.5}, the Laplace-transform of $S_{-1}(\cdot)$
is well-defined; similarly it is given by 
\[
\widehat{S_{-1}}(\lambda)=\frac{1}{\lambda\hat{a}(\lambda)}
(\frac{1}{\hat{a}(\lambda)}I-A_{-1})^{-1}=:H_{-1}(\lambda)
\]
 for all $\operatorname{Re}(\lambda)>0$.
Let $B\in\mathcal{A}_{\infty}^p(U,X)$ and take $v\in U$
and $\lambda\in\mathbb{C}$, such that $\operatorname{Re}(\lambda)>0$. 
The infinite-time
$L^p$-admissibility of $B$ guarantees (see. \cite[Remark 2.2]{Haak2009})
that  the operator 
$\mathcal{B_{\infty}}:L_{c}^p(\mathbb{R}^{+},U)\to X$
given by 
$\mathcal{B_{\infty}}u:=\int_0^{\infty}S_{-1}(t)Bu(t)dt$
possesses a unique extension to a linear bounded operator from 
$L^p(\mathbb{R}^{+},U)$ to $X$  where 
$L_{c}^p(\mathbb{R}^{+},U)$ denotes the space of functions in 
$L^p(\mathbb{R}^{+},U)$ with compact support. Since $(S(t))_{t\geq0}$ 
is exponentially stable, then 
$\mathcal{B_{\infty}}u=\int_0^{\infty}S_{-1}(t)Bu(t)dt$
for every $u\in L^p(\mathbb{R}^{+},U)$. Substituting
$u(t)=ve^{-\lambda t}$ where $v\in U$, we deduce that
there exists $M>0$ such that
\begin{align*}
\| H_{-1}(\lambda)Bv\| 
&=\| \int_0^{\infty}S_{-1}(t)Bve^{-\lambda t}dt\| \\
&\leq  M\| ve^{-\lambda\cdot}\| _{L^p([0,\infty[,U)}
= \frac{M\| v\| _{U}}{p^{1/p}(Re\lambda)^{1/p}}\,.
\end{align*}
Hence
\[
\| H_{-1}(\lambda)B\| _{\mathcal{L}(U,X)}\leq\frac{L_{p}}
{(\operatorname{Re}\lambda)^{1/p}}\,,
\]
 for some constant $L_{p}>0$ depending only on $p$.
\end{proof}

In a similar way we define the extrapolated Favard spaces of $A_{-1}$
denoted by $F^{\alpha}(A_{-1})$ and $\widetilde{F}^{1}(A_{-1})$.
The following results give an extension of \cite[Proposition 15]{Maragh2014}
(i.e. $a(t)=1$).

\begin{theorem} \label{thm53} 
Let \eqref{uncontrolled} admit a bounded resolvent
family {\small{}$(S(t))_{t\geq0}$ on $X$} for $\omega^{+}$-exponentially
bounded $a\in L_{\rm loc}^p(\mathbb{R}^{+})$ with $p\geq1$.
Then, we have the following assertions.
\begin{itemize}
\item[(i)] If $\omega_0(S)<0$ then
 $\mathcal{A}_{\infty}^p(U,X)\subset\mathcal{L}(U,F^{1/p}(A_{-1}))$.

\item[(ii)] If $a$ is non negative satisfying {\rm (H1)},
then $\mathcal{A}_{u}^p(U,X)\subset\mathcal{L}(U,\widetilde{F}^{1/p}(A_{-1}))$.

\item[(iii)] If $a$ is a creep function with $a(0^{+})>0$, then 
$\mathcal{L}(U,\widetilde{F}^{1}(A_{-1}))\subset\mathcal{A}_{\infty}^{1}(U,X)
\subset\mathcal{A}_{u}^p(U,X)$.
\end{itemize}
\end{theorem}

\begin{proof}
Without loss of generality, we may assume that $0\in\rho(A)$.
See \cite{A.Fadili14}.

(i) Let $B\in\mathcal{A}_{\infty}^p(U,X)$ and let
$u_0\in U$ fixed. Thanks to the Claim \ref{Haak09}, there exists
$L_{p}>0$ such that
\[
\| \frac{1}{\lambda\widehat{a}(\lambda)}(\frac{1}{\widehat{a}(\lambda)}I-A_{-1})^{-1}Bu_0\| \leq\frac{L_{p}\| u_0\| }{\lambda^{1/p}}\;\;\lambda>0.
\]
 Equivalently,
\[
\| \lambda^{\frac{1}{p}-1}\frac{1}{\widehat{a}(\lambda)}A_{-1}
(\frac{1}{\widehat{a}(\lambda)}I-A_{-1})^{-1}Bu_0\| _{-1}\leq L_{p}\| u_0\| ,
\]
for all $\lambda>0$ and for some $L_{p}>0$. Hence
\[
\sup_{\lambda>\omega}\| \lambda^{\frac{1}{p}-1}
\frac{1}{\widehat{a}(\lambda)}A_{-1}
(\frac{1}{\widehat{a}(\lambda)}I-A_{-1})^{-1}Bu_0\| _{-1}<L_{p}\| u_0\| ,
\]
 which implies that $Bu_0\in F^{1/p}(A_{-1})$,
and by closed graph theorem we deduce that $B\in\mathcal{L}(U,F^{1/p}(A_{-1}))$.

(ii) Let $B\in\mathcal{A}_{u}^p(U,X)$ and $u_0\in U$,
then $b:=Bu_0$ is uniformly finite-time $L^p$-admissible vector
for $(S(t))_{t\geq0}$. By (H1) and (S3) for $(S_{-1}(t))_{t\geq0}$ 
for all $0<t\leq1$,
we have
\[
\frac{\| S_{-1}(t)b-b\| _{-1}}{((1*a)(t))^{1/p}} 
= \frac{\| A_{-1}\int_0^t a(t-s)S_{-1}(s)bds\| _{-1}}{((1*a)(t))^{1/p}}
= \frac{\| \int_0^t S_{-1}(t-s)ba(s)ds\| }{(\int_0^t a(s)ds)^{1/p}}.
\]
With $u(t):=a(t)$, the uniform finite-time $L^p$-admissibility
of $B$ and (H1) imply that
\[
\frac{\| S_{-1}(t)b-b\| _{-1}}{((1*a)(t))^{1/p}} 
\leq  \frac{M(t)\| a\| _{L^p([0,t])}}{(\int_0^t a(s)ds)^{1/p}}
\leq  \frac{M(t)}{\epsilon_{a}^{1/p}}
 \leq  K
\]
for  some constant $K>0$ and all $0<t\leq t_{a}$ due to
 $\limsup_{t\to0^{+}} M(t)<\infty$,
which implies that $b\in\widetilde{F}^{1/p}(A_{-1})$
if $t_{a}\geq1$. Now, if $t_{a}<1$ we obtain once again that
 $b\in\widetilde{F}^{1/p}(A_{-1})$
due to
\[
\sup_{t_{a}\leq t\leq1} \frac{\| a\| _{L^p([0,t])}}{(1*a)(t)}
\leq\frac{\| a\| _{L^p([0,1])}}{(1*a)(t_{a})}.
\]
Hence $B\in\mathcal{L}(U,\widetilde{F}^{1/p}(A_{-1}))$
thanks to the closed graph theorem.

(iii)  Let $B\in\mathcal{L}(U,\widetilde{F}^{1}(A_{-1}))$,
then $Bu(\cdot)\in\mathcal{L}([0,\infty[,\widetilde{F}^{1}(A_{-1}))$
for all $u\in L^{1}([0,\infty[,U)$. Since $a$ is creep
with $a(0^{+})>0$ and $(A_{-1},a)$ is a generator
of the resolvent family {\small{}$(S_{-1}(t))_{t\geq0}$},
Lemma \ref{thm22} implies that there exists $N>0$ such that 
$\int_0^t S_{-1}(t-s)Bu(s)ds\in D(A_{-1})=X$
for all $t>0$ and we have
\[
\| A_{-1}\int_0^t S_{-1}(t-s)Bu(s)ds\| _{-1}
\leq N\| Bu\| _{L^{1}([0,t],\widetilde{F}^{1}(A_{-1}))}.
\]
Whence,
\[
\| \int_0^t S_{-1}(t-s)Bu(s)ds\|  
\leq  N\| B\| _{\mathcal{L}(U,\widetilde{F}^{1}(A_{-1}))}
 \| u\| _{L^{1}([0,t],U)}
\leq  L\| u\| _{L^{1}([0,\infty[,U),}
\]
for some $L>0$ and all $u\in L^{1}([0,\infty[,U)$ which
implies that $B\in\mathcal{A}_{\infty}^{1}(U,X)$. The
proof of the inclusion $\mathcal{A}_{\infty}^{1}(U,X)\subset\mathcal{A}_{u}^p(U,X)$
is immediate.
\end{proof}

Theorem \ref{thm53} together with Proposition \ref{prop12} give
us the following corollary that is well-known for semigroups (see.
\cite{Maragh2014} for (i) when $p=1$ and \cite{G.Weiss;1989c,staffans2005}
for (ii) when $p\geq1$).

\begin{corollary} \label{cor55} 
Let \eqref{uncontrolled} admit a bounded resolvent
family for $\omega^{+}$-exponentially creep function $a$ with $a(0^{+})>0$.
Then, we have the following assertions.
\begin{itemize}
\item [(i)] $\mathcal{A}_{u}^{1}(U,X) =\mathcal{L}(U,F^{1}(A_{-1})) 
=\mathcal{L}(U,\widetilde{F}^{1}(A_{-1}))$.

\item [(ii)] If $\omega_0(S)<0$, then $\mathcal{A}_{u}^{1}(U,X)
=\mathcal{A}_{\infty}^{1}(U,X)$.
\end{itemize}
\end{corollary}

\begin{remark} \label{rmk55} \rm
Let \eqref{uncontrolled} admit an exponentially bounded
resolvent family $(S(t))_{t\geq0}$ for $\omega$-exponentially
function $a\in L_{\rm loc}^{1}(\mathbb{R}^{+})$ satisfying
(H1). Let us consider the following ``adjoint''
Volterra equation
\begin{equation}
z(t)=z_0+\int_0^t a(t-s)A^{*}z(s)ds,\quad  z_0\in X^{*}.\label{duality}
\end{equation}
where $A^{*}$ is the adjoint operator of $A$ . Then \eqref{duality}
admits a resolvent family, denoted by $(\widetilde{S}(t))_{t\geq0}$
if and only if $D(A^{*})$ is densely defined. If this
is the case we have in addition $\widetilde{S}(t)=S^{*}(t)$
for all $t\geq0$ where $S^{*}(t)$ is the adjoint of $S(t)$.
\end{remark}

\begin{proof}
Since $(S(t))_{t\geq0}$ is exponentially bounded
resolvent family, there exist $M>0$ and $\omega\in\mathbb{R}^{+}$
such that $\| S(t)\| \leq Me^{\omega t}$,
$t\geq0$. Then thanks to Proposition \ref{prop2.5}, we have:
\begin{itemize}
\item[(i)] $\hat{a}(\lambda)\neq0$ and
 $\frac{1}{\hat{a}(\lambda)}\in\rho(A)$ for all $\lambda>\omega$;

\item[(ii)] $H(\lambda):=\frac{1}{\lambda\hat{a}(\lambda)}
(\frac{1}{\hat{a}(\lambda)}I-A)^{-1}$,
the resolvent associated with $(S(t))_{t\geq0}$ satisfies
\[
\| H^{(n)}(\lambda)\| \leq  Mn!(\lambda-\omega)^{-(n+1)} 
\quad \text{for all $\lambda>\omega$  and $n\in\mathbb{N}$}.
\]
\end{itemize}
This implies 
\[
\| (H^{*})^{(n)}(\lambda)\| =\| H^{(n)}(\lambda)\| 
\leq (\lambda-\omega)^{-(n+1)} \quad \text{for all $\lambda>\omega$ and 
$n\in\mathbb{N}$}.
\]
If \eqref{duality} admits a resolvent family $(\widetilde{S}(t))_{t\geq0}$,
then by \cite[Proposition 2.6]{JUNG1999}, $D(A^{*})$
is densely defined. Using Proposition \ref{prop2.5} once again, 
$(\widetilde{S}(t))_{t\geq0}$ becomes exponentially bounded and we have
\[
\widehat{\widetilde{S}}(\lambda) = H^{*}(\lambda)
 = \widehat{S^{*}}(\lambda)\quad \text{for all }\lambda>\omega.
\]
Since the Laplace transform is one-to-one, and that $\widetilde{S}(t)$
and $S^{*}(t)$ are continuous, we obtain $\widetilde{S}(t)=S^{*}(t)$
for every $t\geq0$. Conversely, assume that $D(A^{*})$
is densely defined then the above argument implies that $(S^{*}(t))_{t\geq0}$
is the resolvent family of \eqref{duality} which completes the proof.
\end{proof}

Note that a partial result was obtained in \cite[Theorem 3.1]{Jacob2004b}
when $A$ generates a $\mathcal{C}_0$-semigroup on reflexive Banach
space $X$.

It has been proved in \cite[p. 46]{VanNeerven;1992} (resp. Remark
\ref{rmk55}), that if both $A$ and $A^{*}$ are densely defined (e.g.
if $A$ is densely defined and $X$ is reflexive), then
\[
(X_1)^{*}=(X^{*})_{-1}.
\]
 (resp. $(S^{*}(t))_{t\geq0}$ is exactly the
resolvent family associated with the adjoint Volterra equation \eqref{duality}).
As a first consequence, if $C\in\mathcal{L}(X_1,Y)$; where $Y$
is another Banach space (of observation), is an observation operator
for the Volterra equation \eqref{uncontrolled},
then its adjoint $C^{*}\in\mathcal{L}(Y^{*},(X^{*})_{-1})$
becomes a control operator for Volterra equation \eqref{duality}.
Likewise, it has been proved in \cite[p. 50]{VanNeerven;1992} that
if in addition $A$ is densely defined generalized Hille-Yosida operator
then
\[
(X_{-1})^{*}=(X^{*})_1,
\]

 As a second consequence, if $B\in\mathcal{L}(U,X_{-1})$ is a control
operator for the Volterra equation \eqref{uncontrolled}, then its
adjoint $B^{*}\in\mathcal{L}((X^{*})_1,U^{*})$ becomes
an observation operator for Volterra equation \eqref{duality}. Finally,
as for the semigroups case (see. \cite[Theorem 6.9]{G.Weiss;1989b});
if both $A$ and $A^{*}$ are densely defined and $A$ is a generalized
Hille-Yosida operator, then it is easy to see that there is a natural
duality theorem between admissibility of the control operators and
admissibility of observation operators. That is $B$ is a finite-time
$L^p$-admissible (with $p\in[1,\infty[$) control operator for
$(S(t))_{t\geq0}$ if and only if $B^{*}$ is a finite-time
$L^{\overline{{p}}}$-admissible observation operator for $(S^{*}(t))_{t\geq0}$
with $\frac{1}{p}+\frac{1}{\overline{{p}}}=1$, i.e. there exists
$t_0>0$ such that
\[
\int_0^{t_0}\| B^{*}S^{*}(s)z\| _{U^{*}}^{\overline{{p}}}ds
\leq N(t_0)\| z\| _{X^{*}}^{\overline{{p}}},\quad  z\in D(A^{*}),
\]
and $N(t_0)>0$.
This duality has already been considered in \cite[Section 4]{Jacob2004b},
when $p=2$ and $A$ generates a $\mathcal{C}_0$-semigroup on reflexive
Banach space $X$. In this case, it is well-known that both $A$ and
$A^{*}$ are densely defined and $A$ is a generalized Hille-Yosida
operator. 

We now have the following interesting results that are well-known
for semigroups.

\begin{proposition} \label{Equi}
 Let \eqref{uncontrolled} admit a bounded resolvent
family $(S(t))_{t\geq0}$ for $\omega^{+}$-exponentially
creep function $a$ with $a(0^{+})>0$. If \eqref{duality} admits
a resolvent family (equivalently $\overline{D(A^{*})}=X^{*}$),
then we have the following assertions.
\begin{itemize}
\item [(i)] $\mathcal{A}_{u}^{1}(U,X)=\mathcal{A}^{1}(U,X)$.

\item [(ii)] If $\omega_0(S)<0$, then 
$\mathcal{A}_{u}^{1}(U,X)=\mathcal{A}^{1}(U,X)=\mathcal{A}_{\infty}^{1}(U,X)$.
\end{itemize}
\end{proposition}

\begin{proof}
(i) $\mathcal{A}_{u}^{1}(U,X)\subset\mathcal{A}^{1}(U,X)$
is immediate and it remains only to show that 
$\mathcal{A}^{1}(U,X)\subset\mathcal{A}_{u}^{1}(U,X)$.
Let $B\in\mathcal{A}^{1}(U,X)$, then there exists $t_0>0$
and $M(t_0)>0$ such that
\begin{equation}
\| \int_0^{t_0}S_{-1}(t_0-s)Bu(s)ds\| \leq M(t_0)\| u\| _{L^{1}([0,t_0],U)}.\label{L1}
\end{equation}
Since \eqref{uncontrolled} has an exponentially bounded resolvent
family, \cite[Corollary 1.6]{Pruss93} implies that $A$ is a generalized
Hille-Yosida operator. By Remark \ref{rmk55}, $(S^{*}(t))_{t\geq0}$
is the unique resolvent family for \eqref{duality}. Hence, by duality,
\eqref{L1} is equivalent to 
\[
 \sup_{0<t\leq t_0} \| B^{*}S^{*}(t)z\| _{U^{*}}\leq M(t_0)\| z\| _{X^{*}}
\]
(i.e. $\overline{{p}}=\infty$), which in turns implies that
\begin{equation}
{ \sup_{0<t\leq\tau}}\| B^{*}S^{*}(t)z\| _{U^{*}}
\leq N(\tau)\| z\| _{X^{*}},\label{dual}
\end{equation}
for all $z\in D(A^{*})$  and $0<\tau\leq t_0$
with $N(\tau)\leq M(t_0)$. Using once again
the duality argument, we deduce that \eqref{dual} yields
\[
\| \int_{\text{0}}^{\tau}S_{-1}(\tau-s)Bu(s)ds\| 
\leq M(t_0)\| u\| _{L^{1}([0,\tau],U)}\quad \text{for all }
0<\tau\leq t_0.
\]
Without loss of generality, we assume that $0\in\rho(A)$. Thanks
to (S3) for $(S_{-1}(t))_{t\geq0}$ and for all $b\in X_{-1}$,
we have
\[
\frac{\| S_{-1}(\tau)b-b\| _{-1}}{(1*a)(\tau)} 
= \frac{\| A_{-1}\int_0^{\tau}a(\tau-s)S_{-1}(s)bds\| _{-1}}{(1*a)(\tau)}
= \frac{\| \int_0^{\tau}S_{-1}(\tau-s)ba(s)ds\| }{\int_0^{\tau}a(s)ds}.
\]
Since $a$ is non negative; (H1) is satisfied with $t_{a}=\infty$.
Substituting $u(\tau):=a(\tau)$, the finite-time $L^{1}$- admissibility
of $B$ implies that
\[
\frac{\| S_{-1}(\tau)b-b\| _{-1}}{(1*a)(\tau)} 
\leq  M(t_0),
\]
for all $0<\tau\leq t_0$ which implies that $b\in\widetilde{F}^{1}(A_{-1})$
if $t_0\geq1$. Now, if $t_0<1$ we obtain once again that 
$b\in\widetilde{F}^{1}(A_{-1})$ due to
\[
{ \sup_{t_0\leq\tau\leq1}}\frac{\| S_{-1}(t)b-b\| _{-1}}{(1*a)(t)}
\leq\frac{(M+1)\| b\| _{-1}}{(1*a)(t_0)},
\]
where $M$ is the bound of $(S(t))_{t\geq0}$. 
Thus $B\in\mathcal{L}(U,\widetilde{F}^{1}(A_{-1}))$
according to the closed graph theorem. By virtue of Corollary \ref{cor55}
(i) we obtain $B\in\mathcal{A}_{u}^{1}(U,X)$. Assertion
(ii) is directly obtained from (i) and Corollary \ref{cor55} (i)
and this ends the proof.
\end{proof}

\begin{remark} \label{rmk5.7} \rm
We remark that Corollary \ref{cor55} (i) was proved for the 
$\mathcal{C}_0$-semigroups
(i.e. $a(t)=1)$ in \cite[Corollary 17]{Maragh2014}, and
also implies that the analogue Weiss conjecture is true for this class
of Volterra integral systems. Note that a partial answer to Weiss
conjecture for $p=2$ and for some class of Volterra systems was given
in \cite{JACPRT2007} when $a=1+1*k$ with $k\in W^{1,2}(\mathbb{R}^{+})$
and that the semigroup generated by $A$ is equivalent to a contraction
semigroup on a Hilbert space $X$ and $U$ is finite-dimensional.
Now, we can see that Corollary \ref{cor55} (ii) and Proposition \ref{Equi}
(i) give an affirmative answer to (P2) and (P1)
respectively for some Volterra systems when $p=1$.
\end{remark}


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\end{document}