\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2014 (2014), No. 50, pp. 1--7.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2014 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2014/50\hfil Positive solutions]
{Positive solutions to a nonlinear fractional Dirichlet problem on
the half-line}

\author[H. M\^{a}agli, A. Dhifli \hfil EJDE-2014/50\hfilneg]
{Habib M\^aagli, Abdelwaheb Dhifli}  % in alphabetical order

\address{Habib M\^aagli \newline
King Abdulaziz University, Rabigh Campus, College of Sciences and Arts,
Department of Mathematics, P.O. Box 344, Rabigh 21911, Saudi Arabia}
\email{habib.maagli@fst.rnu.tn}

\address{Abdelwaheb Dhifli\newline
D\'epartement de Math\'ematiques, Facult\'e des Sciences de Tunis,
Campus Universitaire, 2092 Tunis, Tunisia}
\email{dhifli\_waheb@yahoo.fr}

\thanks{Submitted November 28, 2013. Published February 19, 2014.}
\subjclass[2000]{34A08}
\keywords{Fractional differential equation; Dirichlet problem; 
positive solution; \hfill\break\indent Schauder fixed point theorem}

\begin{abstract}
 This concerns the existence of infinitely many positive solutions to the
 fractional differential equation
 \begin{gather*}
 D^{\alpha }u(x)+f(x,u,D^{\alpha -1}u)=0, \quad x>0,\\
 \lim_{x\to 0^{+}}u(x)=0,
 \end{gather*}
 where $\alpha \in (1,2]$ and $f$ is a Borel measurable function in
 $\mathbb{R}^{+}\times \mathbb{R}^{+}\times \mathbb{R}^{+}$
 satisfying some appropriate conditions.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{example}[theorem]{Example}
\newtheorem{remark}[theorem]{Remark}
\allowdisplaybreaks

\section{Introduction}

 Recently, many papers on fractional differential equations have been
published. The motivation for those works stems from the fact that
fractional equations serve as an excellent tool to describe many phenomena
in various fields of science and engineering such as control, porous media,
electrochemistry, viscoelasticity, electromagnetic, etc 
(see \cite{Di,H,Ki,Mi}).
Therefore, the theory of fractional differential equations has been
developed very quickly and the investigation for the existence of solutions
of fractional differential equations has recently attracted a considerable
attention (see \cite{Ao,Ab,A,AN,B,DR,De,Du,K,Ku,L,M,Me,N,Po,S,Z}
and the references therein. 
For instance, in \cite{N}, the first author considered the following nonlinear
fractional differential problem in the half-line $\mathbb{R}^{+}=(0,\infty )$:
\begin{equation}
\begin{gathered}
D^{\alpha }u+f(x,u)=0,    \quad u>0  \\
\lim_{x\to 0^{+}}u(x)=0,
\end{gathered} \label{e1.1}
\end{equation}
where $1<\alpha \leq 2$ and $f$ be a measurable function in 
$\mathbb{R}^{+}\times \mathbb{R}^{+}$ satisfying an appropriate condition. Then, he
established the existence of infinitely many solutions of \eqref{e1.1}.

 In this paper, we extend this result to the  fractional problem
\begin{equation}
\begin{gathered}
D^{\alpha }u+f(x,u,D^{\alpha -1}u)=0, \quad u>0 \text{in }\mathbb{R}^{+}, \\
\lim_{x\to 0^{+}}u(x)=0, 
\end{gathered}  \label{e1.2}
\end{equation}
where $f$ is a Borel measurable function in 
$\mathbb{R}^{+}\times \mathbb{R}^{+}\times \mathbb{R}^{+}$ satisfying 
the following assumptions.
\begin{itemize}
\item[(H1)] $f$ is continuous with respect to the second and third
variable.

\item[(H2)] There exist $h_1$ and $h_2$ two nonnegative measurable
functions on $\mathbb{R}^{+}\times\mathbb{R}^{+}\times\mathbb{R}^{+}$ such
that
\begin{itemize}
\item[(i)] $|f(x,y,z)|\leq h(x,y,z):=yh_1(x,y,z)+zh_2(x,y,z)$ for all $
x,y,z\in \mathbb{R}^{+}$.

\item[(ii)] The function $h_{j}$ is nondecreasing with respect to the
second and the third variables and satisfying 
$ \lim_{(y,z)\to (0,0)}h_{j}(x,y,z)=0$ for $j=1,2$.

\item[(iii)] The integral $\int_{0}^{\infty }h(t,\omega_{\alpha }(t),1)dt$ 
converges, where $\omega _{\alpha }(t):=\frac{t^{\alpha-1}}{\Gamma (\alpha )}$.
\end{itemize}
\end{itemize}
We recall that for a measurable function $v$, the Riemann-Liouville
fractional integral $I^{\beta }v$ and the Riemann-Liouville derivative 
$D^{\beta }v$ of order $\beta >0$ are defined by
\[
I^{\beta }v(x)=\frac{1}{\Gamma (\beta )}\int_{0}^{x}(x-t)^{\beta -1}v(t)dt
\]
and
\[
D^{\beta }v(x) 
=\frac{1}{\Gamma (n-\beta )}\big(\frac{d}{dx}\big)
^{n}\int_{0}^{x}(x-t)^{n-\beta -1}v(t)dt \\
=\big(\frac{d}{dx}\big)^{n}I^{n-\beta }v(x),
\]
provided that the right-hand sides are pointwise defined on $\mathbb{R}^{+}$.
 Here $n=[\beta ]+1$ and $[\beta ]$ means the integer part of the number 
$\beta $ and $\Gamma $ is the Euler Gamma function. 
Moreover, we have the following well-known properties (see \cite{Ki,Po}).
\begin{gather}
I^{\beta }I^{\gamma }v(x)=I^{\beta +\gamma }v(x)\quad\text{for }
x\in \mathbb{R} ^{+},\; v\in L_{\rm loc}^{1}([0,\infty )),\;
\beta +\gamma \geq 1. \label{e1.3}
\\
D^{\beta }I^{\beta }v(x)=v(x),\quad\text{a.e in }
\mathbb{R} ^{+},\; v\in L_{\rm loc}^{1}([0,\infty )),\;\beta >0. \label{e1.4}
\\
D^{\beta}v(x)=0\quad\text{if and only if}\quad 
v(x)=\sum_{j=1}^{n}c_{j}x^{\beta -j}, \label{e1.5}
\end{gather}
where $n$ is the smallest integer greater than or equal to $\beta $ and 
$(c_1,c_2,\dots,c_{n})\in \mathbb{R}^{n}$.

\begin{remark}\label{rmk1} \rm
Let $1<\alpha\leq 2$. Then a simple calculus, gives for $x\geq0$,
\begin{equation} \label{e1.6}
I^{\alpha-1}(1)(x)=\omega_{\alpha}(x).
\end{equation}
\end{remark}

Our main result is the following.

\begin{theorem} \label{thm1}
Assume {\rm (H1)} and {\rm (H2)}. Then problem \eqref{e1.2} has infinitely many
solutions. More precisely, there exists a number $b>0$ such that for each 
$c\in(0,b]$, problem \eqref{e1.2} has a continuous solution $u$ satisfying 
\[
 u(x)=c\omega_{\alpha}(x)+\omega_{\alpha}(x)\int_{0}^{
\infty}\big(1-((1-\frac{t}{x})^{+})^{\alpha-1}\big)f(t,u(t),D^{
\alpha-1}u(t))dt.
\]
and 
\[
 \lim_{x\to \infty}\frac{u(x)}{\omega_{\alpha}(x)}=\lim_{x\to
\infty}D^{\alpha-1}u(x)=c.
\]
\end{theorem}

 Note that Theorem \ref{thm1} generalizes a result established by M\^{a}agli and
Masmoudi \cite{Ma} in the case $\alpha =2$.

 In the sequel, for $\lambda \in \mathbb{R}$, we put 
$\lambda ^{+}=\max (\lambda ,0)$ and we denote by $C([0,\infty ])$ 
the set of continuous functions $v$ on $\mathbb{R}^{+}$ such that 
$\lim_{x\to 0^{+}}v(x)$ and $\lim_{x\to \infty }v(x)$ exist.
It is easy to see that $C([0,\infty ])$ is a Banach space with the norm 
$ \| v\| _{\infty }=\sup_{x\geq 0}|v(x)|$.
Let
\[
E=\{v\in C([0,\infty )):D^{\alpha -1}(\omega _{\alpha }v)\in C([0,\infty ])\}
\]
endowed with the norm $\| v\| =\| D^{\alpha -1}(\omega _{\alpha
}v)\| _{\infty }$. 
Then the map
\begin{gather*}
(E,\| \cdot\| )\to (C([0,\infty ]),\| \cdot\| _{\infty })\\
v\mapsto D^{\alpha -1}(\omega _{\alpha }v)
\end{gather*}
is an isometry. It follows that $(E,\| \cdot\| )$ is a Banach space.
Next we quote some results in the following lemmas that will be used later.

\begin{lemma}[\cite{DR}] \label{lem1}
 Let $f$ be a function in $C([0,\infty ))$ such that $f(0)=0$ and 
$D^{\alpha -1}f$ belongs to $C([0,\infty ))$. Then for $x\geq 0$,
\[
I^{\alpha -1}D^{\alpha -1}f(x)=f(x).
\]
\end{lemma}

\begin{lemma} \label{lem2}
Let $m_1$, $m_2\in \mathbb{R}$ such that $m_1\leq m_2$ and let 
$v\in C([0,\infty))$ such that $D^{\alpha-1}(\omega_{\alpha}v)\in C([0,\infty))$
and $m_1\leq D^{\alpha-1}(\omega_{\alpha}v)(t)\leq m_2$ for all 
$t\geq0$. Then  for each $t\geq 0$,
\[
m_1\leq v(t)\leq m_2.
\]
In particular, $\|v\|_{\infty}\leq
\|D^{\alpha-1}(\omega_{\alpha}v)\|_{\infty}$ and $E\subset C([0,\infty])$.
\end{lemma}

\begin{proof}
Let $v\in C([0,\infty))$ such that 
$D^{\alpha-1}(\omega_{\alpha}v)\in C([0,\infty))$ and
\begin{equation}
m_1\leq D^{\alpha-1}(\omega_{\alpha}v)\leq m_2.
\end{equation}
Using Lemma \ref{lem1} and \eqref{e1.6}, we obtain
\[
m_1\omega_{\alpha} \leq
I^{\alpha-1}D^{\alpha-1}(\omega_{\alpha}v)=\omega_{\alpha}v\leq
m_1\omega_{\alpha}.
\]
This implies that for each $t\geq 0$,
\[
m_1\leq v(t)\leq m_2.
\]
\end{proof}

 Let $\mathcal{F}=\{v\in E: 0\leq D^{\alpha-1}(\omega_{\alpha}v)\leq
1\} $. Then we have the following result.

\begin{lemma} \label{lem3}
Assume {\rm (H2)}. Then the family of functions
\[
\Big\{x\mapsto \int_{0}^{x}(1-\frac{t}{x})^{\alpha-1}f(t,\omega_{
\alpha}(t)v(t),D^{\alpha-1}(\omega_{\alpha}v)(t))dt,\,\,v\in\mathcal{F}
\Big\}
\]
is relatively compact in $C([0,\infty])$.
\end{lemma}

\begin{proof}
For $v\in \mathcal{F}$ and $x>0$, put 
$$
 Sv(x)=\int_{0}^{x}(1- \frac{t}{x})^{\alpha -1}
f(t,\omega _{\alpha }(t)v(t),D^{\alpha -1}(\omega_{\alpha }v)(t))dt.
$$
 By (H2) and Lemma \ref{lem2}, we have for $v\in \mathcal{F}$ and $x>0$,
\begin{align*}
|Sv(x)| 
&\leq \int_{0}^{\infty}|f(t,\omega_{\alpha}(t)v(t),D^{\alpha-1}(\omega_{
\alpha}v)(t))|dt \\
&\leq  \int_{0}^{\infty}
h(t,\omega_{\alpha}(t)v(t),D^{\alpha-1}(\omega_{\alpha}v)(t))dt \\
&\leq  \int_{0}^{\infty} h(t,\omega_{\alpha}(t),1)dt<\infty.
\end{align*}
Thus the family $S(\mathcal{F})$ is uniformly bounded.

Now, we prove the equicontinuity of $S(\mathcal{F})$ in $[0,\infty]$.
Let $x,x'\in \mathbb{R}^{+}$ and $v\in \mathcal{F}$, then we have
\begin{gather*}
|Sv(x)-Sv(x')|\leq \int_{0}^{\infty }|((1-\frac{t}{x}
)^{+})^{\alpha-1}-((1-\frac{t}{x'})^{+})^{\alpha-1}|h(t,\omega_{
\alpha}(t),1)dt,
\\
|Sv(x)|\leq \int_{0}^{x}h(t,\omega_{\alpha}(t),1)dt,
\\
\begin{aligned}
&\big|Sv(x)-\int_{0}^{\infty }f(t,\omega_{\alpha}(t)v(t),
 D^{\alpha-1}(\omega_{\alpha}v)(t))dt\big| \\
&\leq \int_{0}^{\infty }\big(1-((1-\frac{t}{x})^{+})^{\alpha-1}\big)
h(t,\omega_{\alpha}(t),1)dt.
\end{aligned}
\end{gather*}
Using Lebesgue's theorem, we deduce from the above inequalities that 
$S( \mathcal{F})$ is equicontinuous in $[0,\infty]$. 
Hence, by Ascoli's theorem, we conclude that $S(\mathcal{F})$ is relatively
compact in $C([0,\infty])$.
\end{proof}

\section{Proof of Theorem \ref{thm1}}

In the sequel, we denote 
\[
g(x,y,z)=\omega _{\alpha }(x)h_1(x,y,z)+h_2(x,y,z),\quad\text{for }
x,y,z\in \mathbb{R}^{+}.
\]
By (H2) and Lebesgue's theorem, 
\[
\lim_{\beta \to 0}\int_{0}^{\infty }g(t,\beta \omega _{\alpha
}(t),\beta )dt=0.
\]
Hence we can fix a number $0<\beta <1$ such that 
$$
\int_{0}^{\infty }g(t,\beta \omega _{\alpha }(t),\beta )dt\leq \frac{1}{3}.
$$
Let $b=2\beta/3 $ and $c\in (0,b]$. To apply a fixed point
argument, set
\[
\Lambda =\{v\in E:\frac{c}{2}\leq D^{\alpha -1}(\omega _{\alpha }v)\leq
\frac{3c}{2}\}.
\]
Then $\Lambda $ is a nonempty closed bounded and convex set in $E$. Now, we
define the operator $T$ on $\Lambda $ by
\[
Tv(x)=c+\int_{0}^{\infty }\Big(1-((1-\frac{t}{x})^{+})^{\alpha -1}\Big)
f(t,\omega_{\alpha }(t)v(t),D^{\alpha -1}(\omega _{\alpha }v)(t))dt,\quad x>0.
\]
First, we shall prove that the operator $T$ maps $\Lambda $ into itself. Let
$v\in \Lambda $. Using Lemma \ref{lem3}, we deduce that the function $Tv$ is in 
$C([0,\infty ])$.
On the other hand,  for $x\geq 0$ we have
\begin{align*}
\omega _{\alpha }(x)Tv(x)
&=\omega _{\alpha }(x)\Big(c+\int_{0}^{\infty}
f(t,\omega _{\alpha }(t)v(t),D^{\alpha -1}(\omega _{\alpha }v)(t))dt\Big)\\
&\quad -I^{\alpha }\big(f(.,\omega _{\alpha }v,D^{\alpha -1}(\omega _{\alpha }v))
\big)(x).
\end{align*}
Hence, applying $D^{\alpha -1}$ on both sides of this equality, we conclude by
\eqref{e1.6} and \eqref{e1.4} that for each $x\geq 0$,
\[
D^{\alpha -1}(\omega _{\alpha }Tv)(x)=c+\int_{x}^{\infty }f(t,\omega
_{\alpha }(t)v(t),D^{\alpha -1}(\omega _{\alpha }v)(t))dt.
\]
This implies that $D^{\alpha -1}(\omega _{\alpha }Tv)$ is in $C([0,\infty ])$
and $T\Lambda \subset E$. Furthermore, we have for $v\in \Lambda $ and 
$x\geq 0$,
\begin{align*}
|D^{\alpha -1}(\omega _{\alpha }Tv)(x)-c| 
&\leq \int_{0}^{\infty
}|f(t,\omega _{\alpha }(t)v(t),D^{\alpha -1}(\omega _{\alpha }v)(t))|dt \\
&\leq \int_{0}^{\infty }h(t,\omega _{\alpha }(t)v(t),D^{\alpha -1}(\omega
_{\alpha }v)(t))dt \\
&\leq \int_{0}^{\infty }h(t,\frac{3c}{2}\omega _{\alpha }(t),\frac{3c}{2})dt
\\
&=\frac{3c}{2}\int_{0}^{\infty }g(t,\frac{3c}{2}\omega _{\alpha }(t),\frac{
3c}{2})dt \\
&\leq \frac{3c}{2}\int_{0}^{\infty }g(t,\beta \omega _{\alpha }(t),\beta
)dt\leq \frac{c}{2}.
\end{align*}
It follows that for each $x\geq 0$,
\[
\frac{c}{2}\leq D^{\alpha -1}(\omega _{\alpha }Tv)(x)\leq \frac{3c}{2}.
\]
So, we conclude that $\Lambda $ is invariant under $T$. 

Next, we prove that $T\Lambda $ is relatively compact in $(E,\|\cdot\| )$. 
For any $v\in \Lambda $ and $x>0$,
\[
\frac{d}{dx}D^{\alpha -1}(\omega _{\alpha }Tv)(x)=-f(x,\omega _{\alpha
}(x)v(x),D^{\alpha -1}(\omega _{\alpha }v)(x))\quad
\text{a.e. in }\mathbb{R}^{+}.
\]
Since
\[
|\frac{d}{dx}D^{\alpha -1}(\omega _{\alpha }Tv)(x)| 
\leq h(x,\omega _{\alpha }(x)v(x),D^{\alpha -1}(\omega _{\alpha }v)(x)) 
\leq h(x,\omega _{\alpha }(x),1)
\]
and $\int_{0}^{\infty }h(x,\omega _{\alpha }(x),1)dx<\infty $,
it follows that the family
 $\{D^{\alpha -1}(\omega _{\alpha }Tv),\,v\in \Lambda \}$ is equicontinuous 
on $[0,\infty ]$. 
Moreover, $\{D^{\alpha -1}(\omega _{\alpha }Tv),\,v\in \Lambda \}$ 
is uniformly bounded. 
Then from Ascoli's theorem, 
$\{D^{\alpha -1}(\omega _{\alpha }v),\,v\in \Lambda \}$ is relatively compact 
in the space $(C([0,\infty ]),\|\cdot\| _{\infty})$. This implies that $T\Lambda $ 
is relatively compact in $(E,\|\cdot\|)$. 

Now, we  prove the continuity of $T$ in $\Lambda $. Let $(v_{k})$ be a
sequence in $\Lambda $ such that
\[
\| v_{k}-v\| =\| D^{\alpha -1}(\omega _{\alpha }v_{k})-D^{\alpha
-1}(\omega _{\alpha }v)\| _{\infty }\to
0\quad\text{as }k\to \infty .
\]
Then by Lemma \ref{lem2}, $\| v_{k}-v\| _{\infty }\to 0$ 
as $k\to \infty $ and for any $x\in [ 0,\infty ]$,
we have
\begin{align*}
&|D^{\alpha -1}(\omega _{\alpha }Tv_{k})(x)-D^{\alpha -1}(\omega _{\alpha}Tv)(x)| \\
&=|\int_{x}^{\infty }\big[f(t,\omega _{\alpha
}(t)v_{k}(t),D^{\alpha -1}(\omega _{\alpha }v_{k})(t))-f(t,\omega _{\alpha
}(t)v(t),D^{\alpha -1}(\omega _{\alpha }v)(t))\big]dt| \\
&\leq \int_{0}^{\infty }\big|f(t,\omega _{\alpha
}(t)v_{k}(t),D^{\alpha -1}(\omega _{\alpha }v_{k})(t))-f(t,\omega _{\alpha
}(t)v(t),D^{\alpha -1}(\omega _{\alpha }v)(t))\big|dt
\end{align*}
and
\[
|f(t,\omega _{\alpha }(t)v_{k}(t),D^{\alpha -1}(\omega _{\alpha
}v_{k})(t))-f(t,\omega _{\alpha }(t)v(t),D^{\alpha -1}(\omega _{\alpha
}v)(t))|\leq 2h(t,\omega _{\alpha }(t),1).
\]
So, by (H1) and Lebesgue's theorem, 
\[
\| Tv_{k}-Tv\| =\| D^{\alpha -1}(\omega _{\alpha }Tv_{k})-D^{\alpha
-1}(\omega _{\alpha }Tv)\| _{\infty }\to
0\quad\text{as }k\to \infty .
\]
It follows by the Schauder fixed point theorem that there exists 
$v\in \Lambda $ such that $Tv=v$. That is,
\[
v(x)=c+\int_{0}^{\infty }(1-((1-\frac{t}{x})^{+})^{\alpha -1})f(t,\omega
_{\alpha }(t)v(t),D^{\alpha -1}(\omega _{\alpha }v)(t))dt,
\quad \text{for }x>0.
\]
We put $u(x)=\omega _{\alpha }(x)v(x)$. Then for any $x>0$, we have
\begin{equation*} %2.1
u(x)=c\omega _{\alpha }(x)+\omega _{\alpha }(x)\int_{0}^{\infty }(1-((1-
\frac{t}{x})^{+})^{\alpha -1})f(t,\omega _{\alpha }(t)v(t),D^{\alpha
-1}(\omega _{\alpha }v)(t))dt.
\end{equation*}
Moreover,  for $x>0$, we have
\begin{equation} \label{e2.1}
\begin{gathered}
\frac{c}{2}\omega _{\alpha }(x)\leq u(x)\leq \frac{3c}{2}\omega _{\alpha }(x),\\
\lim_{x\to \infty }\frac{u(x)}{\omega _{\alpha }(x)}
=\lim_{x\to \infty }D^{\alpha -1}u(x)=c.
\end{gathered}
\end{equation}
It remains to show that $u$ is a solution of problem \eqref{e1.2}. Indeed,
applying $D^{\alpha }$ on both sides of \eqref{e2.1} we obtain by \eqref{e1.5} and
\eqref{e1.4}, that
\[
D^{\alpha }u(x)=-f(x,u,D^{\alpha -1}u),\quad\text{a.e. in }\mathbb{R}^{+}.
\]
This completes the proof.

\begin{example} \label{examp1} \rm
Let $p,q\geq 0$ such that $\max(p,q)>1$ and let $k$ be a measurable function
satisfying
\[
\int_{0}^{\infty}t^{(\alpha-1)p}|k(t)|dt<\infty.
\]
Then there exists a constant $b>0$ such that for each $c\in (0,b]$, the
 problem
\begin{gather*}
D^{\alpha }u+k(x)u^{p}(D^{\alpha-1 }u)^{q}=0, \quad u>0\quad \text{in }
\mathbb{R}^{+}, \\
\lim_{x\to 0^{+}}u(x)=0, 
\end{gather*} 
has a continuous solution $u$ in $\mathbb{R}^{+}$ satisfying 
$\lim_{x\to 0^{+}}\frac{u(x)}{\omega_{\alpha}(x)}
=\lim_{x\to \infty}D^{\alpha-1 }u(x)=c$ .
\end{example}

\begin{example} \label{examp2} \rm
Let $p>1$ and $q>1$. Let $k_1$ and $k_2$ be two measurable functions
such that
\[
\int_{0}^{\infty}|k_1(t)|t^{p(\alpha-1)}dt<\infty,\quad
\int_{0}^{ \infty}|k_2(t)|dt<\infty.
\]
Then there exists a constant $b>0$ such that for each $c\in (0,b]$, the
 problem
\begin{gather*}
D^{\alpha }u+k_1(x)u^{p}+k_2(x)(D^{\alpha-1 }u)^{q}=0, \quad u>0\quad\text{in }
\mathbb{R}^{+},  \\
\lim_{x\to 0^{+}}u(x)=0 
\end{gather*}
has a continuous solution $u$ in $\mathbb{R}^{+}$ satisfying 
\[
\lim_{x\to 0^{+}}\frac{u(x)}{\omega_{\alpha}(x)}
=\lim_{x\to \infty}D^{\alpha-1 }u(x)=c.
\]
\end{example}

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