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

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2007(2007), No. 177, pp. 1--9.\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 2007 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2007/177\hfil Existence of positive solutions]
{Existence of positive solutions for $p(x)$-Laplacian problems}

\author[G. A. Afrouzi and H. Ghorbani\hfil EJDE-2007/177\hfilneg]
{Ghasem A. Afrouzi, Horieh Ghorbani}  % in alphabetical order

\address{Ghasem A. Afrouzi \newline
Department of Mathematics\\
 Faculty of Basic Sciences \\
 Mazandaran University, Babolsar, Iran}
\email{afrouzi@umz.ac.ir}

\address{Horieh Ghorbani \newline
Department of Mathematics\\
 Faculty of Basic Sciences \\
 Mazandaran University, Babolsar, Iran}
\email{seyed86@yahoo.com}

\thanks{Submitted July 18, 2007. Published December 17, 2007}
\subjclass[2000]{35J60, 35B30, 35B40}
\keywords{Positive radial solutions; $p(x)$-Laplacian problems;
\hfill\break\indent boundary value problems}

\begin{abstract}
 We consider the system of differential equations
 \begin{gather*}
  -\Delta_{p(x)} u=\lambda [g(x)a(u) + f(v)] \quad\text{in }\Omega\\
  -\Delta_{q(x)} v=\lambda [g(x)b(v) + h(u)] \quad\text{in }\Omega\\
   u=v= 0 \quad\text{on } \partial \Omega
 \end{gather*}
 where $p(x) \in C^1(\mathbb{R}^N)$ is a radial symmetric function
 such that  $\sup|\nabla p(x)| < \infty$,
 $1 < \inf p(x) \leq \sup p(x) < \infty$, and where
 $-\Delta_{p(x)} u = -\mathop{\rm div}|\nabla u|^{p(x)-2}\nabla u$
 which is called the $p(x)$-Laplacian.
 We discuss the existence of positive solution via
 sub-super-solutions without assuming  sign conditions on
 $f(0),h(0)$.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]

\section{Introduction}

The study of differential equations and variational problems with
nonstandard $p(x)$-growth conditions has been a new and
interesting topic. Many results have been obtained on this kind
of problems; see for example \cite{f1,f2,f3,f4,f5,f6,z3}.
In \cite{f3,f4} Fan and Zhao give
the regularity of weak solutions for differential equations with
nonstandard $p(x)$-growth conditions. Zhang  \cite{z1} investigated
the existence of positive solutions of the system
\begin{equation}\label{eI}
\begin{gathered}
  -\Delta_{p(x)} u= f(v)  \quad\text{in }\Omega\\
   -\Delta_{p(x)} v= g(u) \quad\text{in }\Omega\\
     u=v= 0 \quad\text{on } \partial \Omega
    \end{gathered}
\end{equation}
where $p(x) \in C^1(\mathbb{R}^N)$ is a function,
 $\Omega \subset \mathbb{R}^N$ is a bounded domain.
The operator $-\Delta_{p(x)} u= -\mathop{\rm div}|\nabla u|^{p(x)-2}\nabla
 u)$ is called $p(x)$-Laplacian. Especially, if $p(x)$
 is a constant $p$, System \eqref{eI} is the well-known $p$-Laplacian system.
There are  many papers on the existence of solutions for $p$-Laplacian
elliptic systems, for example \cite{a1,f1,f2,f3,f4,f5,f6,h1}.

In \cite{h1} the authors consider the existence of positive
weak solutions for the
$p$-Laplacian problem
\begin{equation}  \label{eII}
\begin{gathered}
  -\Delta_p u= f(v)  \quad\text{in }\Omega\\
   -\Delta_p v= g(u) \quad\text{in }\Omega\\
     u=v= 0 \quad\text{on } \partial \Omega\,.
\end{gathered}
\end{equation}
There the first eigenfunctions is used for constructing the
subsolution of $p$-Laplacian problems. Under the
condition
$\lim_{u\to+\infty}f(M(g(u))^{1/(p-1)}/u^{p-1} = 0$,   for all $M > 0$,
the authors show the existence of positive solutions for
problem \eqref{eII}.

In this paper, at first, we consider the existence of
positive solutions of the system
\begin{equation} \label{eP1}
\begin{gathered}
  -\Delta_{p(x)} u= F(x, u, v) \quad\text{in }\Omega\\
   -\Delta_{p(x)} v= G(x, u, v) \quad\text{in }\Omega\\
     u=v= 0 \quad\text{on } \partial \Omega
 \end{gathered}
\end{equation}
 where $p(x) \in C^1(\mathbb{R}^N)$ is a function,
$F(x, u, v) = [g(x)a(u) + f(v)]$,
$G(x, u, v) = [g(x)b(v) + h(u)]$, and $\Omega \subset  \mathbb{R}^N$
is a bounded domain.
Then we consider the system
\begin{equation} \label{eP2}
\begin{gathered}
  -\Delta_{p(x)} u= \lambda F(x, u, v) \quad\text{in }\Omega\\
   -\Delta_{p(x)} v= \lambda G(x, u, v) \quad\text{in }\Omega\\
     u=v= 0 \quad\text{on } \partial \Omega
 \end{gathered}
\end{equation}
 where $p(x) \in C^1(\mathbb{R}^N)$ is a function,
$F(x, u, v) = [g(x)a(u) + f(v)]$,
$G(x, u, v) = [g(x)b(v) + h(u)]$,  $\lambda $ is a positive parameter and
$\Omega \subset \mathbb{R}^N$ is a bounded domain.

To study  $p(x)$-Laplacian problems, we need some
theory on the spaces $L^{p(x)}(\Omega)$,  $W^{1,p(x)}(\Omega)$ and
properties of $p(x)$-Laplacian which we will use later (see \cite{f2}).
If $\Omega \subset \mathbb{R}^N$ is an open domain, write
\[
 C_+(\Omega) = \{h : h \in C(\Omega), h(x)> 1 \text{ for }x \in \Omega \}
\]
$h^+ = \sup_{x \in \Omega} h(x)$,
$h^- = \inf_{x \in \Omega} h(x)$,  for any $h \in C(\Omega)$,
$L^{p(x)}(\Omega) = \{u | u$ is a measurable
real-valued function, $\int_\Omega |u|^{p(x)}dx < \infty \}$.

Throughout the paper, we will assume that $p \in C_+(\Omega)$ and
$1 < \inf_{x \in \mathbb{R}^N}p(x) \leq \sup_{x \in \mathbb{R}^N}p(x) < N$.
We  introduce the norm on $L^{p(x)}(\Omega)$by
\[
|u|_{p(x)} = \inf\{\lambda > 0 : \int_\Omega
|\frac{u(x)}{\lambda}|^{p(x)} dx \leq 1\},
\]
and $(L^{p(x)}(\Omega) ,  |\cdot|_{p(x)})$ becomes a Banach space, we
call it generalized Lebesgue space.
The space $(L^{p(x)}(\Omega) ,  |\cdot|_{p(x)})$ is a separable,
reflexive and uniform convex Banach space (see \cite[Theorem 1.10, 1.14]{f2}).

The space $W^{1,p(x)}(\Omega)$ is defined by
 $W^{1,p(x)}(\Omega) = \{u \in L^{p(x)}(\Omega) :
|\nabla u| \in L^{p(x)}(\Omega)\}$,
and it is equipped with the norm
\[
\|u\| = |u|_{p(x)} + |\nabla u|_{p(x)},  \quad \forall u
\in W^{1,p(x)}(\Omega).
\]
We denote by  $W_0^{1,p(x)}(\Omega)$ the closure of
$C_0^\infty(\Omega)$ in $W^{1,p(x)}(\Omega)$.  $W^{1,p(x)}(\Omega)$
and $W_0^{1,p(x)}(\Omega)$ are separable, reflexive and uniform
convex Banach space (see  \cite[Theorem 2.1]{f2}). We define
\[
(L(u) , v) = \int_{\mathbb{R}^N} |\nabla
u|^{p(x)-2}\nabla u\nabla v dx,  \quad    \forall u, v \in
W^{1,p(x)}(\Omega),
\]
then $L :W^{1,p(x)}(\Omega) \to(W^{1,p(x)}(\Omega))^*$ is a continuous,
bounded and is a strictly monotone operator, and it is a homeomorphism
\cite[Theorem 3.11]{f5}.

Functions  $u,  v $ in $W_0^{1,p(x)}(\Omega)$,  is called a
weak solution of \eqref{eP2}; it satisfies
\begin{gather*}
\int_\Omega |\nabla u|^{p(x)-2}\nabla u \nabla \xi dx
= \int_\Omega \lambda F(x, u, v) \xi dx,  \quad  \forall \xi \in
W_0^{1,p(x)}(\Omega), \\
\int_\Omega |\nabla v|^{q(x)-2}\nabla v \nabla \xi dx
= \int_\Omega \lambda G(x, u, v)\xi dx,  \quad  \forall \xi \in
W_0^{1,p(x)}(\Omega).
\end{gather*}
We make the following assumptions
\begin{itemize}
\item[(H1)]  $p(x) \in C^1(\mathbb{R}^N)$ is a  radial symmetric and
$\sup |\nabla p(x)| < \infty $

\item[(H2)] $\Omega = B(0 , R) = \{x | |x| < R\}$ is a ball,
where $R > 0$ is a sufficiently large constant.

\item[(H3)]  $a,  b \in C^1([0 , \infty))$ are nonnegative,
nondecreasing functions such that
\[
\lim_{u \to+\infty}
\frac{a(u)}{u^{P^- - 1}} = 0,  \quad
 \lim_{u \to+\infty} \frac{b(u)}{u^{P^- - 1}} = 0\,.
\]


\item[(H4)]  $f,  h \in C^1([0, \infty))$ are
nondecreasing functions,  $\lim_{u \to+\infty}f(u) = +\infty$,\\
$ \lim_{u \to+\infty}h(u) = +\infty$, and
\[
\lim_{u \to +\infty}\frac{f(M(h(u))^\frac{1}{p^--1})}{u^{p^--1}} = 0,
\quad \forall M > 0\,.
\]

\item[(H5)] $g : [0,+\infty) \to(0, \infty)$ is a
continuous function such that
$ L_1 = \min_{x\in \bar{\Omega}}g(x)$,  and
$ L_2 = \max_{x\in \bar{\Omega}}g(x)$.

\end{itemize}

We shall establish the following result.


\begin{theorem} \label{thm1}
 If {\em(H1)--(H5)} hold, then \eqref{eP1} has a
positive solution.
\end{theorem}

\begin{proof}
We establish this theorem by constructing
a positive subsolution $(\phi_1 , \phi_2)$ and supersolution
$(z_1, z_2)$ of \eqref{eP1}, such that $\phi_1 \leq z_1$ and
$\phi_2 \leq z_2$. That is $(\phi_1 , \phi_2)$ and $(z_1, z_2)$
satisfy
\begin{gather*}
\int_\Omega |\nabla
\phi_1|^{p(x)-2}\nabla \phi_1 \cdot \nabla \xi  dx \leq
\int_\Omega g(x) a(\phi_1) \xi  dx + \int_\Omega f(\phi_2) \xi  dx,
\\
\int_\Omega |\nabla \phi_2|^{p(x)-2}\nabla
\phi_1 \cdot \nabla \xi  dx \leq  \int_\Omega g(x)b(\phi_2) \xi dx
+  \int_\Omega h(\phi_1) \xi  dx,
\\
\int_\Omega |\nabla z_1|^{p(x)-2}\nabla
z_1 \cdot \nabla \xi  dx \geq  \int_\Omega g(x) a(z_1) \xi  dx +
 \int_\Omega f(z_2) \xi  dx,
\\
 \int_\Omega |\nabla z_2|^{p(x)-2}\nabla
z_2 \cdot \nabla \xi  dx \geq \int_\Omega g(x)b(z_2) \xi  dx +
\int_\Omega h(z_1) \xi  dx,
\end{gather*}
for all $\xi \in W_0^{1,p(x)}(\Omega)$ with
$\xi \geq 0$. Then \eqref{eP1} has a positive solution.

\subsection*{Step  1} We construct a subsolution of \eqref{eP1}.
Denote
\begin{gather*}
\alpha = \frac{\inf p(x)- 1}{4(\sup |\nabla p(x)| +1)},\quad
R_0 = \frac{R-\alpha}{2}, \\
b = \min \{a(0)L_1 + f(0),   b(0)L_1 + h(0),  -1\},
\end{gather*}
 and let
\[
\phi(r) = \begin{cases}
  e^{-k(r-R)} - 1,  & 2R_0 < r \leq R, \\
e^{\alpha k} - 1 + \int_r^{2R_0}(ke^{\alpha
k})^{\frac{p(2R_0)-1}{p(r)-1}}
\\
\times [\frac{(2R_0)^{N-1}}{r^{N-1}}\sin(\varepsilon(r-2R_0)+
\frac{\pi}{2})(L_1 + 1)]^{\frac{1}{p(r)-1}}dr,
& 2R_0-\frac{\pi}{2\varepsilon} < r \leq 2R_0,
\\[3pt]
e^{\alpha k} - 1 + \int_{2R_0- \frac{\pi}{2\varepsilon}}
^{2R_0}(ke^{\alpha
k})^{\frac{p(2R_0)-1}{p(r)-1}}\\
\times [\frac{(2R_0)^{N-1}}{r^{N-1}}\sin(\varepsilon_0(r-2R_0)+
\frac{\pi}{2})(L_1 + 1)]^{\frac{1}{p(r)-1}}dr,
& r \leq 2R_0-\frac{\pi}{2\varepsilon},
\end{cases}
\]
where $R_0$ is sufficiently large, $\varepsilon$ is a
small positive constant which satisfies
$R_0 \leq 2R_0 -\frac{\pi}{2\varepsilon}$,


In the following, we will prove that $(\phi , \phi)$ is
a subsolution of \eqref{eP1}.
Since
\[
\phi'(r) =\begin{cases}
  e^{-k(r-R)} - 1, &  2R_0 < r \leq R,
\\
-(ke^{\alpha k})^{\frac{p(2R_0)-1}{p(r)-1}}\\
\times [\frac{(2R_0)^{N-1}}{r^{N-1}}\sin(\varepsilon(r-2R_0)+
\frac{\pi}{2})(L_1 + 1)]^{\frac{1}{p(r)-1}}dr,
&  2R_0-\frac{\pi}{2\varepsilon} < r \leq 2R_0,
\\
0, & 0 \leq r \leq 2R_0-\frac{\pi}{2\varepsilon},
\end{cases}
\]
it is easy to see that $\phi \geq 0$ is decreasing and
$\phi \in C^1([0 , R]),  \phi(x) = \phi(|x|) \in C^1(\bar{\Omega})$.
Let $r = |x|$. By computation,
\[
-\Delta_{p(x)}\phi = -\mathop{\rm div}|\nabla
\phi(x)|^{p(x)-2}\nabla \phi(x)) =
-(r^{N-1}|\phi'(r)|^{p(r)-2}\phi'(r))'/r^{N-1}.
\]
Then
\[
 -\Delta_{p(x)}\phi=
 \begin{cases}
  (k e^{-k(r-R)})^{p(r)-1} \big[-k(p(r)-1)+ p'(r)\ln k \\
- kp'(r)(r-R) + \frac{N-1}{r}\big],
&   2R_0 < r \leq R,
\\[3pt]
\varepsilon (\frac{2R_0}{r})^{N-1} (ke^{\alpha k})^({p(2R_0)-1})\\
\times \cos(\varepsilon(r-2R_0)+ \frac{\pi}{2})(L_1 + 1),
& 2R_0-\frac{\pi}{2\varepsilon} < r \leq 2R_0,
\\
0, & 0 \leq r \leq 2R_0-\frac{\pi}{2\varepsilon},
\end{cases}
\]
If $k$ is sufficiently large, when $2R_0 < r \leq R$,
then
\[
-\Delta_{p(x)}\phi \leq -k[\inf p(x) -1-
\sup|\nabla p(x)|(\frac{\ln k}{k} + R - r) + \frac{N-1}{kr}] \leq
-k \alpha.
\]
Since $\alpha$ is a constant dependent only on $p(x)$, if
$k$ is a big enough, such that
$-k a < b$,
and since $\phi(x) \geq 0$ and $a, f$ are monotone, this
implies
\begin{equation} \label{e1}
 -\Delta_{p(x)}\phi \leq a(0) L_1 +
f(0)\leq g(x) a(\phi) + f(\phi), \quad   2R_0 < |x| \leq R\,.
\end{equation}
If $k$ is sufficiently large, then
\[
a(e^{\alpha k}- 1) \geq 1,\quad
f(e^{\alpha k}-1) \geq 1 , \quad
b(e^{\alpha k}- 1) \geq 1,\quad
h(e^{\alpha k}- 1) \geq 1
\]
where $k$ is dependent on $a,  f,  b,  h, p$,  and
independent on $R$. Since
\begin{align*}
-\Delta_{p(x)}\phi
&= \varepsilon (\frac{2R_0}{r})^{N-1} (ke^{\alpha
k})^({p(2R_0)-1})\cos(\varepsilon(r-2R_0)+ \frac{\pi}{2})(L_1 +1)\\
& \leq \varepsilon(L_1 + 1) 2^N k^{p^+}e^{\alpha k
p^+} ,  2R_0-\frac{\pi}{2\varepsilon} < |x| < 2R_0\,.
\end{align*}
Let $\varepsilon = 2^{-N} k^{-p^+}e^{-\alpha k p^+}$.
Then
\begin{equation} \label{e2}
-\Delta_{p(x)}\phi \leq L_1 + 1 \leq g(x) a(\phi)  + f(\phi),
   2R_0-\frac{\pi}{2\varepsilon} < |x| < 2R_0.
\end{equation}
Obviously,
\begin{equation} \label{e3}
-\Delta_{p(x)}\phi = 0 \leq L_1 + 1 \leq g(x)a(\phi) + f(\phi),
  |x| <2R_0-\frac{\pi}{2\varepsilon}.
\end{equation}
Since $\phi(x) \in C^1(\Omega)$, combining \eqref{e1}, \eqref{e2},
\eqref{e3}, we have
\[
-\Delta_{p(x)}\phi \leq g(x)a(\phi) + f(\phi)
\]
for a.e. $x \in \Omega$.  Similarly we have
\[
-\Delta_{p(x)}\phi \leq g(x) b(\phi) +h(\phi),
\]
for a.e. $x \in \Omega$.
Let $(\phi_1, \phi_2) = (\phi, \phi)$, since $\phi(x)
\in C^1(\bar{\Omega})$, it is easy to see that $(\phi_1 ,
\phi_2)$ is a subsolution of \eqref{eP1}.



\subsection*{Step  2} We construct a supersolution of \eqref{eP1}
Let $z_1$ be a radial solution of
\begin{gather*}
-\Delta_{p(x)}z_1(x) = (L_2 + 1) \mu,\quad\text{in } \Omega, \\
  z_1 = 0 \quad \text{on }  \partial\Omega\,.
\end{gather*}
We denote $z_1 = z_1(r) = z_1(|x|)$, then $z_1$
satisfies
\[
-(r^{N-1}|z_1'|^{p(r)-2}z_1')' =
r^{N-1}(L_2 + 1)\mu,   z_1(R) = 0, z_1'(0) = 0\,.
\]
Then
\begin{equation} \label{e4}
z_1' = -|\frac{r(L_2 + 1 )\mu}{N}|^{\frac{1}{p(r)-1}},
\end{equation}
and
\[
z_1 = \int_r^R |\frac{r(L_2 + 1
)\mu}{N}|^{\frac{1}{p(r)-1}}dr.
\]
We denote $\beta = \beta((L_2 + 1)\mu) = \max_{0 \leq r
\leq R}z_1(r)$, then
\[
\beta((L_2 + 1)\mu) = \int_0^R |\frac{r(L_2 +
1)\mu}{N}|^{\frac{1}{p(r)-1}}dr = ((L_2 + 1
)\mu)^{\frac{1}{p(q)-1}}\int_0^R
|\frac{r}{N}|^{\frac{1}{p(r)-1}}dr,
\]
where $q \in [0 , 1]$.
Since $\int_0^R |\frac{r}{N}|^{\frac{1}{p(r)-1}}dr$ is
a constant, then there exists a positive constant $C \geq 1$ such
that
\begin{equation} \label{e5}
\frac{1}{C}((L_2 +1)\mu)^{\frac{1}{p^+ -1}} \leq \beta((L_2 +
1)\mu) = \max_{0 \leq r \leq R} z_1(r) \leq C((L_2 + 1)\mu)
^{\frac{1}{p^- - 1}}\,.
\end{equation}
We consider
\begin{gather*}
  -\Delta_{p(x)} z_1 =(L_2 + 1)\mu  \quad\text{in }\Omega\\
  -\Delta_{p(x)} z_2=(L_2 + 1)h(\beta((L_2 + 1)\mu)) \quad\text{in }\Omega\\
  z_1=z_2= 0 \quad\text{on } \partial \Omega\,.
\end{gather*}
Then we shall prove that $(z_1 , z_2)$ is a
supersolution for \eqref{eP1}.
For $\xi \in W^{1,p(x)}(\Omega)$ with $\xi \geq 0$,  it is easy to
see that
\begin{align*}
\int_{\Omega}|\nabla z_2|^{p(x)-2}\nabla z_2 \cdot \nabla \xi dx
&= \int_{\Omega}(L_2 + 1)h(\beta((L_2 + 1 )\mu))\xi dx\\
&\geq \int_{\Omega}L_2 h(\beta((L_2 + 1
)\mu))\xi dx + \int_{\Omega} h(z_1)\xi dx.
\end{align*}
Similar to \eqref{e5}, we have
\[
 \max_{0 \leq r \leq R}z_2(r) \leq C[(L_2
+ 1) h(\beta((L_2 + 1)\mu))]^{\frac{1}{(p^- - 1)}}.
\]
By (H3), for $\mu$ large enough we have
\[
h(\beta((L_2 + 1)\mu)) \geq b(C[(L_2 + 1)
h(\beta((L_2 + 1 )\mu))]^{\frac{1}{p^- - 1}}) \geq
b(z_2).
\]
Hence
\begin{equation} \label{e6}
\int_{\Omega}|\nabla z_2|^{p(x)-2}\nabla z_2 \cdot \nabla \xi dx
\geq \int_{\Omega}g(x) b(z_2)\xi dx + \int_{\Omega}h(z_1) \xi dx,
\end{equation}
Also
\[
\int_{\Omega}|\nabla z_1|^{p(x)-2}\nabla
z_1 \cdot \nabla \xi dx = \int_{\Omega}(L_2 + 1)\mu \xi dx.
\]
By (H3), (H4), when $\mu$ is sufficiently large,
according to \eqref{e5}, we have
\begin{align*}
(L_2 + 1)\mu
&\geq [\frac{1}{C}\beta((L_2 +1 )\mu)]^{p^- - 1}\\
&\geq L_2 a(\beta ((L_2 + 1)\mu)) +
f[C[(L_2 + 1)^{\frac{1}{(p^- - 1)}}(h(\beta((L_2 +
1)\mu)))^{\frac{1}{(p^- - 1)}}] \\
&\geq g(x) a(z_1) +  f(z_2),
\end{align*}
then
\begin{equation} \label{e7}
\int_{\Omega}|\nabla z_1|^{p(x)-2}\nabla z_1 \cdot \nabla \xi dx
\geq \int_{\Omega}g(x) a(z_1) \xi dx + \int_{\Omega}  f(z_2)\xi
dx.
\end{equation}
According to \eqref{e6} and \eqref{e7}, we can conclude that
$(z_1 , z_2)$ is a supersolution of \eqref{eP1}.

Let $\mu$ be sufficiently large, then from \eqref{e4} and the
definition of $(\phi_1 , \phi_2)$, it is easy to see that
$\phi_1 \leq z_1$ and $\phi_2 \leq z_2$. This completes the
proof.
\end{proof}

 Now we consider the problem
\begin{equation} \label{eP2'}
\begin{gathered}
  -\Delta_{p(x)} u=\lambda F(x, u, v) \quad\text{in }\Omega\\
   -\Delta_{p(x)} v=\lambda G(x, u, v) \quad\text{in }\Omega\\
     u=v= 0 \quad\text{on } \partial \Omega.
\end{gathered}
\end{equation}
If $p(x) \equiv p$ (a constant), because of the
homogenity of $p$-Laplacian, \eqref{eP1} and \eqref{eP2} can be
transformed into each other; but, if $p(x)$ is a general
function, since $p(x)$-Laplacian is nonhomogeneous, they cannot
be transformed into each other. So we can see that
$p(x)$-Laplacian problem is more complicated than than that of
$p$-Laplacian, and it is necessary to discuss the problem \eqref{eP2}
separately.

\begin{theorem} \label{thm2}
 If $p(x)\in C^1(\bar{\Omega})$,  $\Omega = B(0, R)$, and
{\rm (H3)--(H5)} hold, then there exists a $\lambda^*$
which is sufficiently large, such that \eqref{eP2} possesses a
positive solution for any $\lambda \geq \lambda^*$.
\end{theorem}

\begin{proof}
We construct a subsolution of \eqref{eP2}.
Let $\beta \leq \frac{R}{4}$ satisfy
\begin{equation} \label{e8}
|p(r_1) - p(r_2)| \leq \frac{1}{2},
  \forall r_1, r_2 \in [R-2\beta, R].
\end{equation}
In the following we denote
\begin{equation} \label{e9}
\begin{gathered}
\delta = \min \{\frac{\inf p(x)-1}{4(\sup |\nabla p(x)| + 1)}\},\quad
p_*^+ = \sup_{R-2\beta \leq |x| \leq R}p(x), \quad
p_*^- = \inf_{R-2\beta \leq |x| \leq R}p(x), \\
b = \min \{a(0) L_1 + f(0),   b(0)L_1 + h(0), -1\}.
\end{gathered}
\end{equation}
Let $\alpha \in (0, \beta]$, and set
\[
\phi(r) = \begin{cases}
  e^{-k(r-R)} - 1,  & R- \alpha < r \leq R,\\
e^{\alpha k} - 1 + \int_r^{R-\alpha}
 (ke^{\alpha k})^{\frac{p(R-\alpha)-1}{p(r)-1}}
[\frac{(R-\alpha)^{N-1}}{r^{N-1}}\\
\times \sin(\varepsilon(r-(R-\alpha))+
\frac{\pi}{2})(L_1 + 1)]^{\frac{1}{p(r)-1}}dr,
& R-2\beta < r \leq R - \alpha,
\\[3pt]
e^{\alpha k} - 1 + \int_{R - \alpha - \frac{\pi}{2\varepsilon}}
^{R - \alpha }(ke^{\alpha k})^{\frac{p(R - \alpha
)-1}{p(r)-1}}[\frac{(R - \alpha)^{N-1}}{r^{N-1}}\\
\times \sin(\varepsilon(r- (R - \alpha))+
\frac{\pi}{2})(L_1 + 1)]^{\frac{1}{p(r)-1}}dr,
& r \leq R - 2\beta,
\end{cases}
\]
where $\varepsilon = \frac{\pi}{2(2\beta - \alpha) }$
which satisfies $\varepsilon(R - 2\beta - (R - \alpha)) +
\frac{\pi}{2} = 0 $.

In the following, we will prove that $(\phi , \phi)$ is
a subsolution of \eqref{eP2}.
Since
\[
\phi'(r) = \begin{cases}
e^{-k(r-R)} - 1,  & R - \alpha < r \leq R,
\\
-(ke^{\alpha k})^{\frac{p(R - \alpha )-1}{p(r)-1}}\\
 [\frac{(R -\alpha )^{N-1}}{r^{N-1}}\\
\times \sin(\varepsilon(r- (R - \alpha))+
\frac{\pi}{2})(L_1 + 1)]^{\frac{1}{p(r)-1}}dr,
&  R - 2\beta < r \leq R - \alpha,
\\
0,  & r \leq R - 2\beta.
 \end{cases}
\]
It is easy to see that $\phi \geq 0$ is decreasing and $\phi \in
C^1([0 , R]),  \phi(x) = \phi(|x|) \in C^1(\Omega)$.

Let $r = |x|$. By computation,
\[
-\Delta_{p(x)}\phi(x) = \begin{cases}
(k e^{-k(r-R)})^{p(r)-1}
[-k(p(r)-1)\\
+ p'(r)\ln k - kp'(r)(r-R) + \frac{N-1}{r}],
&  R - \alpha < r \leq R,
\\[3pt]
\varepsilon (\frac{R - \alpha}{r})^{N-1} (ke^{\alpha k})^{({p(R -
\alpha )-1})}\\
\times \cos(\varepsilon(r- (R - \alpha))+ \frac{\pi}{2})(L_1
+ 1 ), & R - 2\beta < r \leq R - \alpha, \\
0,  & r \leq R - 2\beta.
\end{cases}
\]
If $k$ is sufficiently large, when $R - \alpha < r \leq R$, then we have
\[
-\Delta_{p(x)}\phi \leq -k^{p(r)}[\inf
p(x) -1- \sup|\nabla p(x)|(\frac{\ln k}{k} + R - r) +
\frac{N-1}{kr}] \leq -k^{p(r)} \delta.
\]
 If $k$ satisfies
\begin{equation} \label{e10}
 k^{p_*^-}\delta = -\lambda b ,
\end{equation}
and since $\phi(x) \geq 0$ and $a, f$ is monotone, it
means that
\begin{equation} \label{e11}
 -\Delta_{p(x)}\phi \leq \lambda(a(0) L_1 +
f(0))\leq \lambda (g(x) a(\phi) + f(\phi)),    R - \alpha < |x|
\leq R.
\end{equation}
 From (H3), (H4) there exists a positive constant $M$
such that
$a(M- 1) \geq 1$, $f(M-1) \geq 1$, $b(M- 1) \geq 1$, $h(M- 1) \geq 1 $.
Let
\begin{equation} \label{e12}
\alpha k = \ln M.
\end{equation}
Since
\begin{align*}
-\Delta_{p(x)}\phi(x)
&= \varepsilon
(\frac{R - \alpha}{r})^{N-1} (ke^{\alpha k})^({p(R - \alpha
)-1})\cos(\varepsilon(r-(R - \alpha))+ \frac{\pi}{2})(L_1 + 1)\\
&\leq \varepsilon(L_1 + 1) 2^N (ke^{\alpha k})^{
p_*^+ - 1} ,  R - 2\beta < |x| < R - \alpha ,
\end{align*}
if
\begin{equation} \label{e13}
\varepsilon 2^N (ke^{\alpha k})^{ p_*^+ - 1} \leq \lambda,
\end{equation}
then
\begin{equation} \label{e14}
-\Delta_{p(x)}\phi(x) \leq \lambda( L_1 + 1) \leq \lambda(g(x)
a(\phi) + f(\phi)),  \quad   R - 2\beta < |x| < R - \alpha .
\end{equation}
Obviously
\begin{equation} \label{e15}
-\Delta_{p(x)}\phi(x) = 0 \leq \lambda L_1 + 1
\leq \lambda(g(x)a(\phi) + f(\phi)), \quad  |x| < R - 2\beta \,.
\end{equation}
Combining \eqref{e10}, \eqref{e12} and \eqref{e13}, we only need
\[
\varepsilon 2^N
|\frac{-b}{\delta}\lambda|^\frac{p_*^+ - 1}{p_*^-}M^{p_*^+ - 1}
\leq \lambda,
\]
 and according to \eqref{e8}, \eqref{e9}, we only need
\[
(\frac{\pi}{\beta}2^N M^{p_*^+ -
1}|\frac{-b}{\delta}|^\frac{p_*^+ - 1}{p_*^-})2p_*^- \leq
\lambda\,.
\]
Let
\[
 \lambda^* = (\frac{\pi}{\beta}2^N M^{p_*^+
- 1}|\frac{-b}{\delta}|^\frac{p_*^+ -
1}{p_*^-})^{2p_*^-}\,.
\]
If $\lambda \geq \lambda^*$ is sufficiently large,
then \eqref{e13} is satisfied.

Since $\phi(x) = \phi(|x|) \in C^1(\Omega)$, according to  \eqref{e11},
\eqref{e14} and \eqref{e15}, it is easy to see that if $\lambda$ is
sufficiently large, then $(\phi_1, \phi_2)$ is a subsolution of \eqref{eP2}.

\subsection*{Step  2}
 We construct a supersolution of \eqref{eP2}.
Similar to the proof of Theorem \ref{thm1}, we
consider
\begin{gather*}
 -\Delta_{p(x)} z_1 =\lambda(L_2 + 1)\mu  \quad\text{in }\Omega\\
 -\Delta_{p(x)} z_2=\lambda(L_2 + 1)h(\beta(\lambda(L_2 + 1)\mu))
  \quad\text{in }\Omega\\
 z_1=z_2= 0 \quad\text{on } \partial \Omega\,,
\end{gather*}
where $\beta = \beta(\lambda(L_2 + 1)\mu) = \max_{0
\leq r \leq R}z_1(r)$. It is easy to see that
\begin{align*}
\int_{\Omega}|\nabla z_2|^{p(x)-2}\nabla
z_2 \cdot \nabla \xi dx
&= \int_{\Omega}\lambda(L_2 +
1)h(\beta(\lambda(L_2 + 1 )\mu))\xi dx\\
&\geq \int_{\Omega}\lambda L_2
h(\beta(\lambda(L_2 + 1 )\mu))\xi dx + \int_{\Omega}\lambda
h(z_1)\xi dx.
\end{align*}
Similar to \eqref{e5}, we have
\[
\max_{0 \leq r \leq R}z_2(r) \leq
C[\lambda(L_2 + 1)h(\beta(\lambda(L_2 + 1)\mu))]^{\frac{1}{(p^- -
1)}}.
\]
By (H3) for $\mu$ large enough we have
\[
h(\beta(\lambda(L_2 + 1)\mu)) \geq
b(C[\lambda(L_2 + 1)h(\beta(\lambda(L_2 + 1 )\mu))]^{\frac{1}{p^-
- 1}}) \geq b(z_2).
\]
Hence
\begin{equation} \label{e16}
\int_{\Omega}|\nabla z_2|^{p(x)-2}\nabla z_2 \cdot \nabla \xi dx
\geq \int_{\Omega}\lambda g(x) b(z_2)\xi dx + \int_{\Omega}
\lambda h(z_1) \xi dx.
\end{equation}
Also
\[
\int_{\Omega}|\nabla z_1|^{p(x)-2}\nabla
z_1 \cdot \nabla \xi dx = \int_{\Omega}\lambda(L_2 + 1)\mu \xi dx.
\]
By (H3), (H4),  when $\mu$ is sufficiently large,
according to \eqref{e5}, we have
\begin{align*}
(L_2 + 1)\mu
&\geq \frac{1}{\lambda} [\frac{1}{C}\beta(\lambda(L_2 + 1 )\mu)]^{p^- - 1}\\
&\geq L_2 a(\beta (\lambda(L_2 + 1)\mu)) +
f(C[\lambda(L_2 + 1) h(\beta(\lambda(L_2 + 1)\mu))]^{\frac{1}{(p^-
- 1)}})\,.
\end{align*}
Then
\begin{equation} \label{e17}
\int_{\Omega}|\nabla z_1|^{p(x)-2}\nabla z_1 \cdot \nabla \xi dx
\geq \int_{\Omega}\lambda g(x) a(z_1) \xi dx + \int_{\Omega}
\lambda f(z_2)\xi dx.
\end{equation}
According to \eqref{e16} and \eqref{e17}, we can conclude that
$(z_1 , z_2)$ is a supersolution of \eqref{eP2}.

Similar to the proof of Theorem \ref{thm1}, if $\mu$ is
sufficiently large, we have $\phi_1 \leq z_1$ and
$\phi_2 \leq z_2$. This completes the proof.
\end{proof}


\begin{thebibliography}{00}

\bibitem{a1} J. Ali, R. Shivaji,
\emph{Positive solutions for a class of p-Laplacian systems with
 multiple parametes}, J. Math. Anal. Appl. Article In Press.

\bibitem{c1}C. H. Chen,
\emph{On positive weak solutions for a class of quasilinear elliptic systems},
 Nonlinear Anal. 62  (2005) 751-756.

\bibitem{f1} X. L. Fan, H. Q. Wu, F. Z. Wang,
\emph{Hartman-type results for p(t)-Laplacian systems},
 Nonlinear Anal. 52 (2003) 585-594.

\bibitem{f2} X. L. Fan, D. Zhao, \emph{On the spaces $L^{p(x)}(\Omega)$
and $W^{m,p(x)}(\Omega)$}, J. Math. Anal. Appl. 263 (2001) 424-446.

\bibitem{f3} X. L. Fan, D. Zhao,
\emph{A class of De Giorgi type and H\"{o}lder continuity},
 Nonlinear Anal. TMA 36 (1999) 295-318.

\bibitem{f4} X. L. Fan, D. Zhao,
\emph{The quasi-minimizer of integral functionals with $m(x)$ growth conditions},
 Nonlinear Anal. TMA 39 (2000) 807-816.

\bibitem{f5} X. L. Fan, Q. H. Zhang,
\emph{Existence  of solutions for $p(x)$-Laplacian Dirichlet problem},
 Nonlinear Anal. 52 (2003) 1843-1852.

\bibitem{f6} X. L. Fan, Q. H. Zhang, D. Zhao
\emph{Eigenvalues of $p(x)$-Laplacian Dirichlet problem},
 J. Math. Anal. Appl. 302 (2005) 306-317.

\bibitem{h1}D. D. Hai, R. Shivaji,
\emph{An existence result on positive solutions for a class of p-Laplacian
systems}, Nonlinear Anal. 56 (2024) 1007-1010.

\bibitem{r1}M. R\^{u}zicka,
\emph{Electrorheological Fluids: Modeling and Mathematical Theory},
Lecture Notes in Math, vol. 1784, Springer-Verlag, Berlin, 2000.

\bibitem{z1} Q. H. Zhang,
\emph{Existence of positive solutions for elliptic systems with
nonstandard $p(x)$-growth conditions via sub-supersolution method},
 Nonlinear Anal. 67 (2007) 1055-1067.

\bibitem{z2} Q. H. Zhang,
\emph{Existence of positive solutions for a class of $p(x)$-Laplacian systems},
 J. Math. Anal. Appl. 302 (2005) 306-317.

\bibitem{z3} V. V. Zhikov,
\emph{Averaging of functionals of the calculus of variations and
elasticity theory}, Math. USSR Izv. 29 (1987) 33-36.

\end{thebibliography}

\end{document}