\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2013 (2013), No. 06, pp. 1--6.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2013 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2013/06\hfil Asymptotically periodic solutions]
{Asymptotically periodic solutions for differential and difference
inclusions in \\ Hilbert spaces}

\author[G. Moro\c{s}anu, F. \"Ozpinar \hfil EJDE-2013/06\hfilneg]
{Gheorghe Moro\c{s}anu, Figen \"Ozpinar}  % in alphabetical order

\address{Gheorghe Moro\c{s}anu \newline
Department of Mathematics and its Applications\\
Central European University\\
Budapest, Hungary}
\email{morosanug@ceu.hu}

\address{Figen \"Ozpinar \newline
Bolvadin Vocational School\\
Afyon Kocatepe University\\
Afyonkarahisar, Turkey}
\email{fozpinar@aku.edu.tr}

\thanks{Submitted October 18, 2012. Published January 8, 2013.}
\subjclass[2000]{39A10, 39A11, 47H05, 34G25}
\keywords{Differential inclusion; difference inclusion; subdifferential;
\hfill\break\indent maximal monotone operator;  
weak convergence; strong convergence}

\begin{abstract}
Let $H$ be a real Hilbert space and let $A:D(A)\subset H\to H$ be a
(possibly set-valued) maximal monotone operator. We
investigate the existence of asymptotically periodic solutions to
the differential equation (inclusion)
$u'(t) + Au(t)\ni f(t) + g(t)$, $t>0$, where
$f \in L_{\rm loc}^2(\mathbb{R}_+,H)$ is a $T$-periodic
function ($T>0$) and $g \in L^1(\mathbb{R}_+,H)$. Consider also the
following difference inclusion (which is a discrete analogue of the
above inclusion): $ \Delta u_n + c_n A u_{n+1}\ni f_n + g_n
, \ n=0,1, \dots$, where $(c_n)\subset (0,+\infty)$,
$(f_n)\subset H$ are $p$-periodic sequences for a positive integer
$p$ and $(g_n)\in \ell^{1}(H)$. We investigate the weak or strong
convergence of its solutions to $p$-periodic sequences. We show that
the previous results due to  Baillon, Haraux (1977) and
Djafari Rouhani, Khatibzadeh (2012) corresponding to $g\equiv 0$,
respectively $g_n=0$, $n=0,1,\dots$, remain valid for
 $g\in L^1(\mathbb{R}_+,H)$, respectively $(g_n)\in l^1(H)$.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\allowdisplaybreaks

\section{Introduction}\label{intro}

Let $H$ be a real Hilbert space with inner product 
$(\cdot, \cdot)$ and the induced Hilbertian norm $\Vert \cdot \Vert$. 
Let $A:D(A)\subset H\to H$ be a (possibly multivalued) maximal
monotone operator. Consider the following differential equation (inclusion)
\begin{equation}
\frac{{d}u}{{d}t}(t) + Au(t)\ni f(t)+ g(t),\quad t>0, 
\label{Ec}
\end{equation}
where $f \in L_{\rm loc}^2(\mathbb{R}_+,H)$ is a $T$-periodic function for a
given $T>0$ and $g \in L^1(\mathbb{R}_+,H)$. In this paper we investigate the
behavior at infinity of solutions to \eqref{Ec}.

Consider also the following difference equation (inclusion) (which is the
discrete analogue of \eqref{Ec})
\begin{equation}
\Delta u_n + c_n A u_{n+1}\ni f_n + g_n,\quad n=0,1,\dots,
 \label{ODE}
\end{equation}
where $(c_n)\subset (0,+\infty)$, $(f_n)\subset H$ are
$p$-periodic sequences for a positive integer $p$, $(g_n)\in
\ell^{1}(H):=\{u=(u_{1},u_{2},\dots):\sum_{n=1}^{\infty } \Vert
u_n\Vert <\infty\}$ and $\Delta$ is the difference operator
defined as usual, i.e., $\Delta u_n= u_{n+1}-u_n$. We
investigate the weak or strong convergence of
solutions to $p$-periodic sequences.

More precisely, in this article  we show that the previous results 
due to Baillon, Haraux \cite{Haraux77} and Djafari Rouhani, Khatibzadeh 
\cite{Hadi} related to the equations (inclusions),
\begin{equation}
\frac{{d}u}{{d}t}(t) + Au(t)\ni f(t),\quad t>0, 
\label{Ec0}
\end{equation}
and
\begin{equation}
\Delta u_n + c_n A u_{n+1}\ni f_n,\quad n=0,1,\dots , \label{ODE0}
\end{equation}
respectively, remain valid for \eqref{Ec} and \eqref{ODE}, where
$g\in L^1(\mathbb{R}_+,H)$ and $(g_n)\in l^1(H)$.


\section{Preliminaries}\label{pr}

To obtain our main results we recall the following results on the
existence of asymptotically periodic solutions of the equations
 \eqref{Ec0} and \eqref{ODE0}.

\begin{lemma}[{\cite{Haraux77}, \cite[p. 169]{Morosanu88}}]  \label{prlm1}
Assume that $A$ is the subdifferential of a proper, convex, and
lower semicontinuous function
$\varphi:H\to(-\infty,+\infty]$, $A=\partial \varphi$. Let
$f \in L_{\rm loc}^2(\mathbb{R}_+,H)$ be a $T$-periodic function (for a given
$T>0$). Then, equation \eqref{Ec0} has a solution bounded on $\mathbb{R}_+$
if and only if it has at least a $T$-periodic solution. In this case
all solutions of \eqref{Ec0} are bounded on $\mathbb{R}_+$ and for every
solution $u(t)$, $t \geq 0$, there exists a $T$-periodic solution
$q$ of \eqref{Ec0} such that
\[
u(t)- q(t)\to 0,  \quad\text{as  } t\to \infty ,
\]
weakly in $H$.
Moreover, every two periodic solutions of \eqref{Ec0} differ by an
additive constant, and
\[
\frac{{d}u_n}{{d}t}\to \frac{{d}q}{{d}t},\quad  \text{as  }
n\to \infty,
\]
strongly in $L^2(0,T;H)$, where $u_n(t)=u(t+nT)$, $n=1,2,\dots$
\end{lemma}

\begin{lemma}[\cite{Hadi}, \cite{Morosanu12}] \label{prlm2}
Assume that $A:D(A)\subset H \to H$ is a maximal monotone
operator. Let $c_n>0$ and $f_n \in H$ be $p$-periodic sequences;
i.e., $c_{n+p}=c_n$, $f_{n+p}=f_n$ $(n=0,1,\dots )$, for a given
positive integer $p$. Then  \eqref{ODE0} has a bounded
solution if and only if it has at least one $p$-periodic solution.
In this case all solutions of \eqref{ODE0} are bounded and for every
solution $(u_n)$ of \eqref{ODE0} there exists a $p$-periodic
solution $(\omega_n)$ of \eqref{ODE0} such that
\[
u_n-\omega_n\to 0, \quad \text{weakly in $H$, as $n\to \infty$.}
\]
Moreover, every two periodic solutions differ by an additive
constant vector.
\end{lemma}


\section{Results on asymptotically periodic solutions}\label{mr}

We begin this section with the following result regarding the
continuous case, which is an extension of Lemma \ref{prlm1}.

\begin{theorem}\label{mrthm1}
Assume that $A:D(A)\subset H \to H$ is the subdifferential
of a proper, convex, lower semicontinuous function
$\varphi:H\to(-\infty,+\infty]$, $A=\partial\varphi$. 
Let $f\in L_{\rm loc}^2(\mathbb{R}_+,H)$ be a $T$-periodic function ($T>0$) and let
$g \in L^1(\mathbb{R}_+,H)$. Then equation \eqref{Ec} has a bounded solution if
and only if equation \eqref{Ec0} has at least a $T$-periodic
solution. In this case all solutions of \eqref{Ec} are bounded on
$\mathbb{R}_+$ and for every solution $u(t)$ of \eqref{Ec} there exists a
$T$-periodic solution $\omega(t)$ of \eqref{Ec0} such that
\[
u(t) - \omega(t)\to 0, \quad\text{ weakly in $H$,  as
$t\to \infty$.}
\]
\end{theorem}

\begin{proof}
If a solution $u(t)$, $t \geq 0$, of equation \eqref{Ec} is bounded
on $\mathbb{R}_+$, then any other solution $\tilde{u}(t)$, $t \geq 0$, of
equation \eqref{Ec} is also bounded, because
\begin{equation}
\Vert u(t) - \tilde{u}(t)\Vert \leq \Vert u(0) -
\tilde{u}(0)\Vert.\label{thm1.1}
\end{equation}
If a solution $u(t)$ of \eqref{Ec} is bounded, then any solution
$v(t)$ of \eqref{Ec0} is bounded and conversely, because
\[
\Vert u(t)-v(t)\Vert \leq \Vert u(0)-v(0)\Vert + \int_0^t \Vert
g(s)\Vert{d}s \leq \Vert u(0)-v(0)\Vert + \int_0^{\infty} \Vert
g(s)\Vert{d}s < \infty,
\]
for $t\ge 0$.
Thus, the first part of the theorem follows by Lemma \ref{prlm1}.
To prove the second part, we define $g_m: \mathbb{R}_+ \to H$
as follows:
\[
g_{m}(t)= \begin{cases}
g(t) &\text{for a.e. } t \in (0, m) \\
0 &\text{if } t\ge m,
\end{cases}
\]
where $m=1,2, \dots$.

Let $u(t)$, $t\ge 0$, be an arbitrary bounded solution of
\eqref{Ec}. For each $m=1,2,\dots$ denote by $u_m(t)$, $t\ge 0$,
the solution of the Cauchy problem
\begin{gather}
\frac{{d}u_m(t)}{{d}t} + A(u_m(t))\ni f(t)+ g_m(t),\quad t>0, \label{Ecm}
\\
u_{m}(0)= u(0).  \label{ICcm}
\end{gather}
Since $u_m(t)$, $t\ge m$, is a solution of equation \eqref{Ec0}, it
follows by Lemma \ref{prlm1} that there is a $T$-periodic solution
$q_m(t)$ of \eqref{Ec0}, such that
\begin{equation}
u_m(t) - q_m(t)\to 0, \quad \text{weakly in $H$,  as 
$t\to \infty$.} \label{thm1.2}
\end{equation}
In fact, since any two periodic solutions of \eqref{Ec0} differ by
an additive constant (cf. Lemma \ref{prlm1}), it follows that
\[
q_m(t) = q(t) + c_m, \quad m=1,2, \dots,
\]
for a fixed periodic solution $q(t)$ of \eqref{Ec0}, where $(c_m)$
is a sequence in $H$. Thus, \eqref{thm1.2} becomes
\begin{equation}
u_m(t) - q(t) \to c_m \quad \text{as } t\to \infty,
\label{99}
\end{equation}
weakly in $H$. Moreover,
\begin{equation}
\frac{{d}q(t)}{{d}t} + A(q(t) + c_m)\ni f(t). \label{thm1.3}
\end{equation}
On the other hand, it is easy to see that, for all $m < r$, we have
\[
\Vert [u_m(t) - q(t)] - [u_r(t) - q(t)] \Vert = \Vert u_m(t) -
u_r(t)\Vert \le \Vert u(0)-u(0)\Vert + \int_m^r \Vert g(t) \Vert \,
dt.
\]
Therefore, taking the limit as $t\to \infty$, it follows
(see \eqref{99}),
\begin{equation}
\Vert c_m - c_r \Vert \le \int_m^r \Vert g(t) \Vert \, dt,
\end{equation}
which shows that $(c_m)$ is a convergent sequence; i.e., there
exists a point $a\in H$, such that
\begin{equation}
\Vert c_m - a\Vert \to 0, \quad \text{as } m\to \infty.
\label{9999}
\end{equation}
Since $A$ is maximal monotone (hence demiclosed), we can pass to the
limit in \eqref{thm1.3}, as $m \to \infty$, to deduce that
$\omega (t) := q(t) + a$ is a solution of \eqref{Ec0} (which is
$T$-periodic). Note also that
\begin{equation}
\Vert u(t) - u_m(t) \Vert \le \int_m^t \Vert g(s) \Vert \, ds \le
 \int_m^{\infty} \Vert g(s) \Vert \, ds, \ t\ge m. \label{99999}
\end{equation}
To conclude, we use the decomposition
\[
\begin{split}
u(t) - \omega(t)
&= [u(t)-u_m(t)] + [u_m(t)-q_m(t)] + [q_m(t) - \omega(t)] \\
&= [u(t)-u_m(t)] + [u_m(t) - q(t) - c_m] + [(q(t) + c_m) -(q(t) +a)],
\end{split}
\]
which shows that $u(t) - \omega(t)$ converges weakly to zero, as
$t \to \infty$ (cf. \eqref{99}, \eqref{9999}, \eqref{99999}).
In other words, $u(t)$ is asymptotically periodic with respect to
the weak topology of $H$.
\end{proof}

 It is well known that, even in the case $g\equiv 0$, the above 
result (Theorem \ref{mrthm1}) is not
valid for a general maximal monotone operator $A$, so we cannot
expect more in our case.

\begin{theorem}\label{mrthm2} \rm
Assume that $A:D(A)\subset H \to H$ is a maximal monotone
operator. Let $(g_n)\in \ell^{1}(H)$ and let $c_n>0$, 
$f_n \in H$ be $p$-periodic sequences, i.e., $c_{n+p}=c_n$, $f_{n+p}=f_n$
$(n=0,1,\dots )$, for a given positive integer $p$. Then equation
\eqref{ODE} has a bounded solution if and only if equation
\eqref{ODE0} has at least one $p$-periodic solution. In this case
all solutions of \eqref{ODE} are bounded and for every solution
$(u_n)$ of \eqref{ODE} there exists a $p$-periodic solution
$(\omega_n)$ of \eqref{ODE0} such that
\[
u_n-\omega_n\to 0, \quad\text{weakly in $H$, as $n\to \infty$.}
\]
\end{theorem}

\begin{proof}
Consider the initial condition
\begin{equation}
u_{0}= x,  \label{IC}
\end{equation}
for a given $x \in H$. We can rewrite equation \eqref{ODE} in the form:
\[
u_{n+1}-u_n + c_n A u_{n+1}\ni f_n+g_n.
\]
The solution of the problem \eqref{ODE}-\eqref{IC} is calculated
successively from
\[
u_{n+1}=\big(I+ c_n A\big)^{-1}\big( u_n+f_n+g_n\big),\quad
n=0,1, \dots,
\]
in a unique manner, which will give a unique solution
$(u_n)_{n\geq0}$.

If a solution $(u_n)$ of \eqref{ODE} is bounded, then any other
solution $(\tilde{u}_n)$ of \eqref{ODE} is bounded, because
\begin{equation}
\Vert u_n-\tilde{u}_n\Vert \leq \Vert u_{0}-\tilde{u}_{0} \Vert
\quad \text{for } n=0,1, \dots \label{thm2.1}
\end{equation}
If a solution $(u_n)$ of \eqref{ODE} is bounded, then any solution
$(v_n)$ of \eqref{ODE0} is bounded and conversely, because
\[
\Vert u_n-v_n\Vert \leq \Vert u_0-v_0\Vert + \sum_{k=0}^{n-1} \Vert
g_k\Vert \leq \Vert u_0-v_0\Vert + \sum_{k=0}^{\infty} \Vert
g_k\Vert < \infty .
\]
According to Lemma \ref{prlm2} the first part of the theorem is
proved. For the second part we define $(g_{n,m})_{n,m\ge 0}$ as
follows:
\[
g_{n,m}=
\begin{cases}
g_n  &\text{if } n < m, \\
0  &\text{if } n\ge m.
\end{cases}
\]
Let $(z_n)$ be an arbitrary solution of \eqref{ODE} (which is
bounded). For each $m=0,1,\dots$ denote by $(z_{n,m})_{n\ge 0}$ the
(unique) solution of the problem
\begin{gather}
z_{n+1,m}-z_{n,m} + c_n A z_{n+1,m} \ni f_n+g_{n,m}
 \label{ODEm} \\
z_{0,m}= z_{0}.  \label{ICm}
\end{gather}
Note that $(z_{n,m})_{n\ge m}$ is a solution of equation
\eqref{ODE0}. By Lemma \ref{prlm2} there is a $p$-periodic (with
respect to $n$) solution ($\omega_{n,m}$) of \eqref{ODE0} such that
\begin{equation}
z_{n,m} - \omega_{n,m}\to 0, \quad \text{weakly in $H$,  as
$n\to \infty$.} \label{thm2.2}
\end{equation}
For each $m\ge 0$ we have
\begin{gather*}
\omega_{1,m}-\omega_{0,m}+ c_{0} A \omega_{1,m} \ni f_0, \\
\omega_{2,m}-\omega_{1,m}+ c_{1} A \omega_{2,m} \ni f_1, \\
\dots \\
\omega_{p,m}-\omega_{p-1,m}+ c_{p-1} A \omega_{p,m} \ni f_{p-1},
\end{gather*}
where $\omega_{p,m} = \omega_{0,m}$. Since any two periodic
solutions of \eqref{ODE0} differ by an additive constant, we can
write
\begin{equation}
\omega_{t,m} = \zeta_{t} + a_m \quad t \in \{0,1, \dots, p-1\},
\label{thm2.3}
\end{equation}
where $(\zeta_t)$ is a an arbitrary but fixed periodic solution of
\eqref{ODE0}, and ${(a_m)}_{m\ge 0}$ is a sequence in $H$. Thus
\begin{equation}
\begin{gathered}
\zeta_{1}-\zeta_{0}+ c_{0} A (\zeta_{1}+a_m) \ni f_0, \\
\zeta_{2}-\zeta_{1}+ c_{1} A (\zeta_{2}+a_m) \ni f_1, \\
\dots \\
\zeta_{p}-\zeta_{p-1}+ c_{p-1} A (\zeta_{p}+a_m) \ni f_{p-1}, \\
\end{gathered}\label{thm2.4}
\end{equation}
for all $m\ge 0$, where $\zeta_p = \zeta_{0}$. Also we can rewrite
\eqref{thm2.2} as
\begin{equation}
z_{kp+t,m} \to \zeta_t + a_m, \quad \text{weakly in $H$,
as $k\to \infty$}, \label{100}
\end{equation}
for $m \ge 0$ and $t\in \{ 0,1, \dots, p-1\} $. On the other hand,
for $0\le m < r$, we have (cf. \eqref{ODEm}, \eqref{ICm})
$$
\Vert z_{kp+t,m} - z_{kp+t,r} \Vert \le \sum_{j=m}^{r-1}\Vert
g_j\Vert.
$$
According to \eqref{100} this implies
\begin{equation}
\Vert a_m - a_r\Vert \le \sum_{j=m}^{r-1}\Vert g_j\Vert \le
\sum_{j=m}^{\infty}\Vert g_j\Vert,
\end{equation}
for all $0\le m< r$, so there exists an $a\in H$ such that
\begin{equation}
\Vert a_m - a \Vert \to 0, \quad \text{as } m\to \infty.
 \label{1000}
\end{equation}
Since $A$ is maximal monotone (hence demiclosed), we can pass to the
limit in \eqref{thm2.4} as $m\to \infty$ to obtain
\begin{gather*}
\zeta_{1}-\zeta_{0}+ c_{0} A (\zeta_{1}+a) \ni f_0, \\
\zeta_{2}-\zeta_{1}+ c_{1} A (\zeta_{2}+a) \ni f_1, \\
\dots \\
\zeta_{p}-\zeta_{p-1}+ c_{p-1} A (\zeta_{p}+a) \ni f_{p-1}, \\
\end{gather*}
where $\zeta_p = \zeta_0$. So $\omega_n : = \zeta_n + a$  is a
$p$-periodic solution of equation \eqref{ODE0}. We can also see that
\begin{equation}
\Vert z_n - z_{n,m} \Vert \le \Vert z_0 - z_{0,m}\Vert +
\sum_{j=m}^{n-1} \Vert g_j\Vert \le \sum_{j=m}^{\infty} \Vert g_j
\Vert .
 \label{10000}
\end{equation}
Finally, for all natural $n$, we have $n=kp+t$, $t\in \{ 0,1,\dots,p-1
\}$, and
\begin{align*}
z_n-\omega_n
&= [z_n-z_{n,m}] + [z_{n,m} - \omega_{t,m}] +[\omega_{t,m} - \omega_n]\\
&= [z_n-z_{n,m}] + [z_{kp+t,m} - \zeta_t -a_m] + [\zeta_t + a_m -
\zeta_t - a],
\end{align*}
thus the conclusion of the theorem follows by \eqref{100},
\eqref{1000} and \eqref{10000}.
\end{proof}

If in addition $A$ is strongly
monotone, then we can easily extend Theorem 2 in \cite{Morosanu12},
as follows.

\begin{theorem} \label{mrthm3}
Assume that $A:D(A)\subset H \to H$ is a maximal monotone
operator, that is also strongly monotone; i.e., there is a constant
$b>0$, such that
\[
(x_1-x_2, y_1-y_2)\ge b{\Vert x_1-x_2\Vert}^2, \quad
\forall  x_i\in D(A), \; y_i\in Ax_i, \; i=1,2.
\]
Let $c_n>0$ and $f_n \in H$ be $p$-periodic sequences for a
given positive integer $p$ and $(g_n)\in \ell^{1}(H)$. Then
equation \eqref{ODE0} has a unique $p$-periodic solution
$(\omega_n)$ and for every solution $(u_n)$ of \eqref{ODE} we
have
\[
u_n-\omega_n\to 0, \quad\text{strongly in $H$,  as }
n\to \infty.
\]
\end{theorem}
The proof relies on arguments similar to the one above.


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Anal., 67(1977), 101-109.

\bibitem{Hadi} B.~Djafari Rouhani, H.~Khatibzadeh;
\emph{Existence and asymptotic behaviour of solutions to first- and
second-order difference equations with periodic forcing}, J.
Difference Eqns Appl., DOI:10.1080/10236198.2012.658049.

\bibitem{Morosanu88} G.~Moro\c{s}anu;
\emph{Nonlinear evolution equations and applications.} D.Reidel,
Dordrecht-Boston-Lancaster-Tokyo, 1988.

\bibitem{Morosanu12} G.~Moro\c{s}anu and F.~\"{O}zp\i nar;
\emph{Periodic forcing for some difference equations in Hilbert
spaces}, Bull. Belgian Math. Soc. (Simon Stevin), to appear.

\end{thebibliography}

\end{document}