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

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2008(2008), No. 99, pp. 1--10.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu  (login: ftp)}
\thanks{\copyright 2008 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2008/99\hfil Third-order three-point BVP]
{Positive solutions of a third-order three-point boundary-value problem}

\author[B. Yang\hfil EJDE-2008/99\hfilneg]
{Bo Yang}

\address{Bo Yang\newline
Department of Mathematics and Statistics, Kennesaw State
University, GA 30144, USA}
\email{byang@kennesaw.edu}

\thanks{Submitted June 18, 2008. Published July 25, 2008.}
\subjclass[2000]{34B18, 34B10}
\keywords{Fixed point theorem; cone; multi-point boundary-value problem; 
\hfill\break\indent upper and lower estimates}

\begin{abstract}
 We obtain upper and lower estimates for positive solutions of
 a third-order three-point boundary-value problem.
 Sufficient conditions for the existence and nonexistence of
 positive solutions for the problem are also obtained.
 Then to illustrate our results, we include an example.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{example}[theorem]{Example}

\section{Introduction}

Recently third-order multi-point boundary-value problems have
attracted a lot of attention. In 2003, Anderson \cite{A}
considered the third-order boundary-value problem
\begin{gather}
u'''(t) = f(t,u(t)), \quad 0\le t\le 1, \label{ae1} \\
u(t_1) = u'(t_2) = \gamma u(t_3)+ \delta u''(t_3) = 0. \label{ab1}
\end{gather}
In 2008, Graef and Yang \cite{GY} studied the third-order nonlocal
boundary-value problem
\begin{gather}
u'''(t) = g(t)f(u(t)), \quad 0\le t\le 1, \label{ee1} \\
u(0) = u'(p) = \int_q^1 w(t)u''(t)dt = 0.\label{ee2}
\end{gather}
For more results on third-order boundary-value problems we refer
the reader to \cite{AAK,CMS,GSZ,HT,M,WZ,W}.

In this paper, we consider the third-order three-point nonlinear
boundary-value problem
\begin{gather}
u'''(t) = g(t)f(u(t)), \quad 0\le t\le 1, \label{bhu} \\
u(0)-\alpha u'(0)= u'(p) = \beta u'(1)+\gamma u''(1) = 0. \label{rfv}
\end{gather}
%
To our knowledge, the problem \eqref{bhu}-\eqref{rfv} has not been
considered before. Note that the set of boundary conditions \eqref{rfv}
is a very general one. For example, if we let $\alpha=\beta=0$
and $p=\gamma=1$, then \eqref{rfv} reduces to
\begin{equation}
u(0) = u'(1) = u''(1) = 0, \label{rfvvv}
\end{equation}
which are often referred to as the $(1,2)$ focal boundary conditions.
If we let $\alpha=0$, $\beta=0$, and $\gamma=1$, then \eqref{rfv}
reduces to
\begin{equation}
u(0) = u'(p) = u''(1) = 0. \label{rfvv}
\end{equation}
The boundary-value problem that consists of the equation
\eqref{bhu} and the boundary conditions \eqref{rfvv} has been
considered by Anderson and Davis in \cite{AD} and Graef and Yang
in \cite{GY-2}. Our goal in this paper is to generalize some of
the results from \cite{AD,GY-2} to the problem
\eqref{bhu}-\eqref{rfv}.

In this paper, we are interested in the existence and nonexistence
of positive solutions of the problem \eqref{bhu}-\eqref{rfv}.
By a positive solution, we mean a solution $u(t)$ to the
boundary-value problem such that $u(t)>0$ for $0<t<1$.

In this paper, we assume that
\begin{itemize}
\item[(H1)] The functions $f:[0,\infty)\to [0,\infty) $ and
 $g:[0,1]\to [0,\infty)$ are continuous, and $g(t)\not\equiv 0$ on $[0,1]$.
\item[(H2)] The parameters $\alpha$, $\beta$, $\gamma$, and $p$
 are non-negative constants such that $\beta+\gamma>0$, $0< p\le 1$,
 and $2p(1+\alpha)\ge 1$.
\item[(H3)] If $p=1$, then $\gamma>0$.
\end{itemize}

To prove some of our results, we will use the following fixed point theorem,
which is due to Krasnosel'skii \cite{K}.

\begin{theorem} \label{tt1}
Let $(X,\|\cdot\|)$ be a Banach space over the reals, and let
$P\subset X$ be a cone in $X$.
Assume that $\Omega_1,\Omega_2 $ are bounded open subsets of
$X$ with $0\in\Omega_1\subset \overline{\Omega_1}\subset \Omega_2$,
and let
$$
L:P\cap( \overline{\Omega_2}-\Omega_1 )\to P
$$
be a completely continuous operator such that, either
\begin{itemize}
\item[(K1)] $\|Lu\|\leq\|u\|$ if $u\in P\cap\partial \Omega_1$, and $
   \|Lu\|\ge\|u\|$ if $u\in P\cap\partial \Omega_2$; or
\item[(K2)] $\|Lu\|\geq\|u\|$ if $u\in P\cap\partial \Omega_1$, and $
   \|Lu\|\le\|u\|$ if $u \in P\cap\partial \Omega_2 $.
\end{itemize}
Then $L$ has a fixed point in $P\cap( \overline{\Omega_2}-\Omega_1)$.
\end{theorem}

Before the Krasnosel'skii fixed point theorem can be used to obtain
any existence result, we have to find some nice estimates to
positive solutions to the problem \eqref{bhu}--\eqref{rfv} first.
These a priori estimates are essential to a successful application
of the Krasnosel'skii fixed point theorem. It is based on these
estimates that we can define an appropriate cone, on which
Theorem~\ref{tt1} can be applied. Better estimates will result
in sharper existence and nonexistence conditions.

We now fix some notation. Throughout we let $X=C[0,1]$ with the
supremum norm
$$
    \|v\|=\max_{t\in [0,1]} |v(t)|,\quad \forall v\in X.
$$
Obviously $X$ is a Banach space. Also we define the constants
\begin{gather*}
    F_0=\limsup_{x\to 0^+}\frac{f(x)}{x},\quad
    f_0=\liminf_{x\to 0^+}\frac{f(x)}{x}, \\
    F_{\infty}=\limsup_{x\to + \infty} \frac{f(x)}{x},\quad
    f_{\infty}=\liminf_{x\to + \infty} \frac{f(x)}{x}.
\end{gather*}
These constants will be used later in our statements of the existence
theorems.

This paper is organized as follows.
In Section 2, we obtain some {a priori} estimates to positive solutions
to the problem \eqref{bhu}-\eqref{rfv}. In Section 3, we define
a positive cone of the Banach space $X$ using the estimates obtained
in Section 2, and apply Theorem \ref{tt1} to establish some existence
results for positive solutions of the problem \eqref{bhu}-\eqref{rfv}.
In Section 4, we present some nonexistence results.
An example is given at the end of the paper to illustrate the existence
and nonexistence results.

\section{Green's Function and Estimates of Positive Solutions}

In this section, we shall study Green's function for the
problem \eqref{bhu}-\eqref{rfv}, and prove some estimates for positive
solutions of the problem. Throughout the section, we define the constant
$M=\beta+\gamma-\beta p$. By conditions (H2) and (H3), we know that $M$
is a positive constant.

\begin{lemma} \label{dfg}
If $u\in C^3[0,1]$ satisfies the boundary conditions \eqref{rfv} and
$u'''(t)\equiv~0$ on $[0,1]$, then $u(t)\equiv 0$ on $[0,1]$.
\end{lemma}

\begin{proof}
Since $u'''(t)\equiv 0$ on $[0,1]$, there exist constants $a_1$, $a_2$,
and $a_3$ such that
\[
u(t)=a_1+a_2t+a_3t^2,\quad 0\le t\le 1.
\]
Because $u(t)$ satisfies the boundary conditions \eqref{rfv}, we have
\begin{equation}
\begin{pmatrix}
1 & -\alpha & 0                \\
0 &       1 & 2p               \\
0 &   \beta & 2(\beta+\gamma) \end{pmatrix}
\begin{pmatrix}a_1\cr a_2\\ a_3\end{pmatrix}
=\begin{pmatrix}0\\ 0\\ 0 \end{pmatrix}.
\label{cvb}
\end{equation}
The determinant of the coefficient matrix for the above linear system
is $2M>0$. Therefore, the system \eqref{cvb} has only the trivial
solution $a_1=a_2=a_3=0$.
Hence $u(t)\equiv 0$ on $[0,1]$. The proof is complete.
\end{proof}

We need the indicator function $\chi$ to write the expression of Green's
function for the problem \eqref{bhu}-\eqref{rfv}. Recall that if
$[a,b]\subset R:=(-\infty,+\infty)$ is a closed interval,
then the indicator function $\chi$ of $[a,b]$ is given by
\[
\chi_{[a,b]}(t)=
\begin{cases}
1, & \mbox{if }t\in [a,b],     \\
0, & \mbox{if }t\not\in [a,b].
\end{cases}
\]
Now we define the function $G:[0,1]\times[0,1]\to [0,\infty)$ by
\begin{align*}
G(t,s)&=\frac{\beta +\gamma-\beta s}{2( \beta
+\gamma -p\beta)} (2\alpha p + 2pt - t^2)
+ \frac{(t-s)^2}{2}\chi_{[0,t]}(s)\\
&\quad -\frac{p-s}{2(\beta +\gamma -p\beta)}
(2(\alpha + t)(\beta+\gamma)-\beta t^2) \chi_{[0,p]}(s).
\end{align*}
We are going to show that $G(t,s)$ is Green's function for the
problem \eqref{bhu}-\eqref{rfv}.


\begin{lemma}\label{seed}
Let $h\in C[0,1]$. If
\[
y(t)=\int_0^1 G(t,s)h(s)ds, \quad 0\le t\le 1,
\]
then $y(t)$ satisfies the boundary conditions \eqref{rfv}
and $y'''(t)=h(t)$ for $0\le t\le 1$.
\end{lemma}

\begin{proof}
If
\[ y(t)=\int_0^1 G(t,s)h(s)ds,
\]
then
\begin{equation}
\begin{aligned}
y(t)&=-\int_0^p \frac{p-s}{2M}
(2(\alpha + t)(\beta+\gamma)-\beta t^2) h(s)ds
 + \int_0^t\frac{(t-s)^2}{2}h(s)ds
\\
&\quad + \int_0^1\frac{\beta +\gamma-\beta s}{2M} (2\alpha p
+ 2pt - t^2) h(s)ds.
\end{aligned} \label{gg}
\end{equation}
Differentiating the above expression, we have
\begin{equation}
\begin{aligned}
y'(t)&=-\int_0^p \frac{p-s}{M}
(\beta+\gamma-\beta t) h(s)ds
+\int_0^t (t-s) h(s)ds \\
&\quad + \int_0^1\frac{\beta +\gamma-\beta s}{M} (p - t) h(s)ds,
\end{aligned}\label{ggg}
\end{equation}
\begin{equation}
y''(t)= \beta \int_0^p \frac{p-s}{M} h(s)ds
+\int_0^t h(s)ds
- \int_0^1\frac{\beta +\gamma-\beta s}{M} h(s)ds,
\label{gggg}
\end{equation}
and
\[
y'''(t)=h(t),\quad 0\le t\le 1.
\]
It is easy to see from \eqref{ggg} that $y'(p)=0$.

By making the substitution $t=0$ in \eqref{gg} and \eqref{ggg}, we get
\begin{equation}
y(0)= -\int_0^p \frac{p-s}{M}
\alpha (\beta+\gamma) h(s)ds
+ \int_0^1\frac{\beta +\gamma-\beta s}{M}  \alpha p  h(s)ds\label{gg1}
\end{equation}
and
\begin{equation}
y'(0)=-\int_0^p \frac{p-s}{M} (\beta+\gamma) h(s)ds
+ \int_0^1\frac{\beta +\gamma-\beta s}{M}  p h(s)ds.\label{ggg1}
\end{equation}
It is clear from \eqref{gg1} and \eqref{ggg1} that $y(0)-\alpha y'(0)=0$.


By making the substitution $t=1$ in \eqref{ggg} and \eqref{gggg}, we get
\[
y'(1)=-\gamma\int_0^p \frac{p-s}{M} h(s)ds
+\int_0^1 (1-s) h(s)ds
+ \int_0^1\frac{\beta +\gamma-\beta s}{M}\cdot (p-1) h(s)ds
\]
and
\[
y''(1)=
\beta \int_0^p \frac{p-s}{M} h(s)ds
+\int_0^1 h(s)ds
-\int_0^1\frac{\beta +\gamma-\beta s}{M} h(s)ds.
\]
Simplifying the last two equations, we get
\begin{gather}
y'(1)= -\gamma\int_0^p \frac{p-s}{M} h(s)ds
+\gamma \int_0^1 \frac{p-s}{M} h(s)ds, \label{ggglt}\\
y''(1)=\beta \int_0^p \frac{p-s}{M} h(s)ds
-\beta \int_0^1\frac{p-s}{M} h(s)ds.\label{gggg1}
\end{gather}
It is easily seen from \eqref{ggglt} and \eqref{gggg1} that
$\beta y'(1)+\gamma y''(1)=0$.
The proof is now complete.
\end{proof}


\begin{lemma} \label{lem2.3}
Let $h\in C[0,1]$ and $y\in C^3[0,1]$. If $y(t)$ satisfies the boundary
conditions \eqref{rfv} and $y'''(t)=h(t)$ for $0\le t\le 1$, then
\[
y(t)=\int_0^1 G(t,s)h(s)ds, \quad 0\le t\le 1.
\]
\end{lemma}

\begin{proof}
Suppose that $y(t)$ satisfies the boundary conditions \eqref{rfv}
and $y'''(t)=h(t)$ for $0\le t\le 1$. Let
\[
k(t)=\int_0^1 G(t,s)h(s)ds, \quad 0\le t\le 1.
\]
By Lemma \ref{seed} we have $k'''(t)=h(t)$ for $0\le t\le 1$, and
$k(t)$ satisfies the boundary conditions \eqref{rfv}.
If we let $m(t)=y(t)-k(t)$, $0\le t\le 1$, then $m'''(t)=0$
for $0\le t\le 1$  and $m(t)$ satisfies the boundary conditions \eqref{rfv}.
By Lemma \ref{dfg}, we have $m(t)\equiv 0$ on $[0,1]$, which implies that
\[
y(t)=\int_0^1 G(t,s)h(s)ds, \quad 0\le t\le 1.
\]
The proof is complete.
\end{proof}

We see from the last two lemmas that
\[
y(t)=\int_0^1 G(t,s)h(s)ds
\quad \mbox{for } 0\le t\le 1
\]
if and only if $y(t)$ satisfies the boundary conditions \eqref{rfv} and
$y'''(t)=h(t)$ for $0\le t\le 1$. Hence the problem \eqref{bhu}-\eqref{rfv}
is equivalent to the integral equation
\begin{equation}
u(t) =\int_0^1 G(t,s)g(s)f(u(s))ds,\quad 0\le t\le 1,
\label{ee3}
\end{equation}
and $G(t,s)$ is Green's function for the problem \eqref{bhu}-\eqref{rfv}.

Now we investigate the sign property of $G(t,s)$. We start with a technical
lemma.

\begin{lemma} \label{lem2.4}
If {\rm (H2)} holds, then
\[
2p\alpha + 2pt - t^2\ge 0, \quad 0\le t\le 1.
\]
\end{lemma}

\begin{proof}
Assuming  that (H2) holds; if $0\le t\le 1$, then
\[
2p\alpha + 2pt - t^2 = t(1-t)+2p\alpha(1-t)+(2p(1+\alpha)-1)t\ge 0.
\]
The proof is complete.
\end{proof}

\begin{lemma} \label{lem2.5}
If {\rm (H2)--(H3)} hold, then we have
\begin{enumerate}
\item If $0\le t\le 1$ and $0\le s\le 1$, then $G(t,s)\ge 0$.
\item If $0< t<1$ and $0< s< 1$, then $G(t,s)>0$.
\end{enumerate}
\end{lemma}

\begin{proof}
We shall prove (1) only. We take four cases to discuss the sign
property of $G(t,s)$.
\begin{itemize}
\item[(i)] If $s\ge p$ and $s\ge t$, then
\[
G(t,s)=\frac{\beta+\gamma-\beta s}{2M}
(2p\alpha + 2pt - t^2)\ge 0.
\]
\item[(ii)] If $s\ge p$ and $s\le t$, then
\[
G(t,s)=\frac{\beta+\gamma-\beta s}{2M}
(2p\alpha + 2pt - t^2)+\frac{(t-s)^2}{2}\ge 0.
\]
\item[(iii)] If $s\le p$ and $s\ge t$, then
\[
G(t,s)=\frac{1}{2}(2 \alpha s +2st-t^2)\ge 0.
\]
\item[(iv)] If $s\le p$ and $s\le t$, then
\[
G(t,s)=\alpha s+\frac{s^2}{2}\ge 0.
\]
\end{itemize}
Therefore $G(t,s)$ is nonnegative in all four cases.
The proof of (1) is complete.

If we take a closer look at the expressions of $G(t,s)$ in the four cases,
then we will see easily that (2) is also true. We leave the details to
the reader.
\end{proof}

\begin{lemma} \label{tt2}
If $u\in C^3[0,1]$ satisfies \eqref{rfv}, and
\begin{equation}
u'''(t)\ge 0 \quad \text{for } 0\le t\le 1, \label{ee5}
\end{equation}
then
\begin{enumerate}
\item $u(t)\ge 0$ for $0\le t\le 1$.
\item $u'(t)\ge 0$ on $[0,p]$ and $u'(t)\le 0$ on $[p,1]$.
\item $u(p) = \|u\|$.
\end{enumerate}
\end{lemma}

\begin{proof} Note that $G(t,s)\ge 0$ if $t,s\in[0,1]$.
If $u'''(t)\ge 0$ on $[0,1]$, then for each $t\in[0,1]$ we have
\[
u(t)=\int_0^1 G(t,s)u'''(s)\,ds\ge 0.
\]
The proof of (1) is complete.

It follows from \eqref{ggg} that
\[
u'(t)= \int_t^p (s-t)u'''(s)\,ds
+\int_p^1\frac{\beta +\gamma-\beta s}{M}\cdot(p-t)u'''(s)ds.
\]
If $0\le t\le p$, then it is obvious that $u'(t)\ge 0$. If $t\ge p$,
then we put \eqref{ggg} into an equivalent form
\[
u'(t)= -\int_p^t \frac{(s-p)(\gamma+\beta(1-t))}{M}u'''(s)\,ds
 -\int_t^1 \frac{\beta +\gamma-\beta s}{M}(t-p)u'''(s)\,ds,
\]
from which we can see easily that $u'(t)\le 0$.

Part (3) of the lemma follows immediately from parts (1) and (2).
The proof is now complete.
\end{proof}

Throughout the remainder of the paper, we define the continuous
function $a:[0,1]\to[0,+\infty)$ by
\[
a(t)=\frac{2p\alpha+2pt-t^2}{2p\alpha + p^2},\quad 0\le t\le 1.
\]
It can be shown that
\[
a(t)\geq \min\{t,1-t\},\quad 0\le t\le 1.
\]
The proof of the last inequality is omitted.

\begin{lemma} \label{lem2.7}
If $u\in C^3[0,1]$ satisfies \eqref{ee5} and the boundary conditions
\eqref{rfv}, then $u(t)\ge a(t)u(p)$ on $[0,1]$.
\end{lemma}

\begin{proof}
If we define
\[
h(t) = u(t) - a(t)u(p),\quad 0\le t\le 1,
\]
then
\[
h'''(t)=u'''(t)\geq 0,\quad 0\le t\le 1.
\]
Obviously we have $h(p)=h'(p)=0$. To prove the lemma, it suffices
to show that $h(t)\ge 0$ for $0\le t\le 1$. We take two cases to continue
the proof.

\noindent Case I: $h'(0)\le 0$.
 We note that $h'(p)=0$ and $h'$ is concave upward on $[0,1]$.
Since $h'(0)\le 0$, we have $h'(t)\le 0$ on $[0,p]$ and $h'(t)\ge 0$
on $[p,1]$. Since $h(p)=0$, we have $h(t)\ge 0$ on $[0,1]$.

\noindent Case II: $h'(0)>0$.
 It is easy to see from the definition of $h(t)$ that
\[
h(0)=\alpha h'(0).
\]
Since $\alpha\ge 0$, we have $h(0)\ge 0$.

Because $h'(0)>0$ and $h(0)\ge 0$, there exists $\delta\in(0,p)$ such
that $h(\delta)>0$.

By the mean value theorem, since $h(\delta)>h(p)=0$, there exists
$r_1\in(\delta,p)$ such that $h'(r_1)<0$. Now we have $h'(0)>0$, $h'(r_1)<0$,
and $h'(p)=0$. Because $h'(t)$ is concave upward on $[0,1]$, there
exists $r_2\in (0,r_1)$ such that
\[
h'(t)>0\quad \text{on  } [0,r_2), \quad
h'(t)\le 0 \quad \text{on } [r_2,p],\quad
h'(t)\ge 0 \quad \text{on  } (p,1].
\]
Since $h(0)\ge 0$ and $h(p)=0$, we have
$h(t)\geq 0$  on $[0,1]$.

We have shown that $h(t)\geq 0$ on $[0,1]$ in both cases.
The proof is complete.
\end{proof}

In summary, we have

\begin{theorem}\label{uhj}
Suppose that {\rm (H1)--(H3)} hold. If $u\in C^3[0,1]$ satisfies
\eqref{ee5} and the boundary conditions \eqref{rfv}, then
$u(p)=\|u\|$ and $u(t)\ge a(t)u(p)$ on $[0,1]$.
 In particular, if $u\in C^3[0,1]$ is a nonnegative solution to
the boundary-value problem \eqref{bhu}-\eqref{rfv}, then
$u(p)=\|u\|$ and $u(t)\ge a(t)u(p)$ on $[0,1]$.
\end{theorem}

\section{Existence of Positive Solutions}

Now we give some notation. Define the constants
\[
    A = \int_0^1 G(p,s) g(s) a(s)\,ds,\quad
    B = \int_0^1 G(p,s) g(s) \,ds
\]
and let
$$
P=\{v\in X : v(p)\ge 0 ,
\, a(t)v(p)\le v(t)\le v(p) \text{  on \ } [0,1]\}.
$$
Obviously $X$ is a Banach space and $P$ is a positive cone of $X$.
Define an operator $T:P\to X$ by
$$
Tu(t)= \int_0^1 G(t,s)g(s)f(u(s))ds,\quad 0\leq t\leq 1,\; u\in X.
$$
It is well known that $T:P\to X$ is a completely continuous operator.
And by the same argument as in Theorem \ref{uhj} we can prove
that $T(P)\subset P$.

Now the integral equation \eqref{ee3} is equivalent to the
equality
$$
Tu=u,\quad u\in P.
$$
To solve  problem \eqref{bhu}-\eqref{rfv} we need only to find a fixed
point of $T$ in $P$.

\begin{theorem} \label{tt6}
If $BF_0 <1< A f_{\infty}$, then the problem \eqref{bhu}-\eqref{rfv}
has at least one positive solution.
\end{theorem}

\begin{proof}
Choose $\epsilon>0$ such that $(F_0+\epsilon)B\le 1$.
There exists $H_1 >0 $ such that
$$
f(x)\leq (F_0+\epsilon)x \quad\text{for } 0<x\leq H_1.
$$
For each $u\in P$ with $\|u\|=H_1$, we have
\begin{align*}
(Tu)(p) & = \int_0^1 G (p,s) g(s) f(u(s))\,ds\\
&\le \int_0^1 G(p,s) g(s) (F_0+\epsilon)u(s)\,ds\\
& \leq (F_0+\epsilon)\|u\| \int_0^1 G(p,s) g(s)ds\\
&= (F_0+\epsilon)\|u\| B
\le \|u\|,
\end{align*}
which means $ \|Tu\|\leq \|u\| $. So, if we let
$\Omega_1=\{ u\in X: \|u\|<H_1\}$, then
$$
\|Tu\|\leq \|u\|,\quad  \text{for } u\in P\cap\partial\Omega_1.
$$
To construct $\Omega_2$, we first choose $c\in (0,1/4)$ and $\delta>0$
such that
$$
(f_\infty-\delta)\int_c^{1-c} G(p,s) g(s) a(s)\,ds >1.
$$
There exists $ H_3 >0 $ such that
$f(x)\geq (f_\infty-\delta)x$ for $x\geq H_3$.
Let $H_2=H_1 + {H_3}/{c}$.
If $u\in P$ with $\|u\| = H_2$, then for $c\le t\le 1-c$, we have
$$
u(t)\geq\min\{t,1-t\}\|u\| \ge c H_2\ge H_3.
$$
So, if $u\in P$ with $\|u\| = H_2$, then
\begin{align*}
(Tu)(p)
& \geq  \int_c^{1-c} G(p,s) g(s) f(u(s))\,ds\\
&\ge  \int_c^{1-c} G(p,s) g(s) (f_\infty-\delta)u(s)ds\\
& \geq \int_c^{1-c} G(p,s) g(s) a(s)\,ds\cdot (f_\infty-\delta) \|u\|
\ge \|u\|,
\end{align*}
which implies $ \|Tu\|\geq \|u\| $. So, if we let
$\Omega_2=\{ u\in X\,|\ \|u\|<H_2\}$, then
$\overline{\Omega_1}\subset \Omega_2$, and
$$
\|Tu\|\geq \|u\|,\quad \text{for } u\in P\cap\partial\Omega_2.
$$
Then the condition (K1) of Theorem \ref{tt1} is satisfied,
and so there exists a fixed point of $T$ in $P$.
The proof is complete.
\end{proof}

\begin{theorem} \label{tt7}
If $B F_{\infty}< 1< A f_0$, then  \eqref{bhu}-\eqref{rfv}
has at least one positive solution.
\end{theorem}

The proof of the above theorem is similar to that of Theorem \ref{tt6}
and is therefore omitted.

\section{Nonexistence Results and Example}

In this section, we give some sufficient conditions for the nonexistence
of positive solutions.

\begin{theorem} \label{tt8}
Suppose that {\rm (H1)--(H3)} hold.
If $Bf(x)<x$ for all $x\in(0,+\infty)$, then  \eqref{bhu}-\eqref{rfv}
has no positive solution.
\end{theorem}

\begin{proof}
Assume the contrary that $u(t)$ is a positive solution of
 \eqref{bhu}-\eqref{rfv}. Then $u\in P$, $u(t)>0$ for $0<t<1$, and
\begin{align*}
u(p)& =  \int_0^1 G(p,s) g(s)f(u(s))\,ds\\
& < B^{-1} \int_0^1 G(p,s) g(s) u(s)\,ds \\
& \leq  B^{-1}\int_{0}^{1} G(p,s) g(s) ds\cdot u(p)
\le u(p),
\end{align*}
which is a contradiction.
\end{proof}

In a similar fashion, we can prove the following theorem.

\begin{theorem} \label{tt9}
Suppose that {\rm (H1)--(H3)} hold.
If $A f(x)>x$ for all $x\in(0,+\infty)$, then  \eqref{bhu}-\eqref{rfv}
has no positive solution.
\end{theorem}

We conclude this paper with an example.

\begin{example}\rm
Consider the third-order boundary-value problem
\begin{gather}
u'''(t)=g(t)f(u(t)), \quad 0<t<1, \label{rfv2} \\
u(0)-u'(0)=u'(3/4)=u'(1)+u''(1)=0, \label{rfv3}
\end{gather}
where
\begin{gather*}
g(t)=(1+t)/10,\quad 0\le t\le 1, \\
f(u)=\lambda u\frac{1+3u}{1+u}, \quad u\ge 0.
\end{gather*}
Here $\lambda$ is a positive parameter.
Obviously we have $F_0=f_0=\lambda$, $F_{\infty}=f_{\infty}=3\lambda$.
Calculations indicate that
$$
A=\frac{198989}{2112000},\quad B=\frac{9889}{102400}.
$$
From Theorem \ref{tt6} we see that if
$$
3.538 \approx\frac{ 1}{ 3A } < \lambda < \frac{1}{B}\approx 10.355,
$$
then problem \eqref{rfv2}-\eqref{rfv3} has at least one positive solution.
From Theorems \ref{tt8} and \ref{tt9}, we see that if
$$
\lambda<\frac{ 1 }{3B}\approx 3.45 \quad\text{or}\quad
\lambda>\frac{1}{A}\approx 10.613,
$$
then problem \eqref{rfv2}-\eqref{rfv3} has no positive solution.

This example shows that our existence and nonexistence conditions
are quite sharp.
\end{example}

\subsection*{Acknowledgment}
The author is grateful to the anonymous referee for his/her careful
reading of the manuscript and valuable suggestions for its improvement.

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\end{document}