Open Journal of Mathematical Analysis
ISSN: 2616-8111 (Online) 2616-8103 (Print)
DOI: 10.30538/psrp-oma2019.0046
Existence of solution for a nonlinear fifth-order three-point boundary value problem
Laboratory of fundamental and applied mathematics, University of Oran 1, Ahmed Ben Bella, Es-senia, 31000 Oran, Algeria.; (Z.B)
Laboratory of fundamental and applied mathematics, University of Oran 1, Ahmed Ben Bella, Es-senia, 31000 Oran, Algeria.; (S.B)
\(^1\)Corresponding Author: zouaouibekri@yahoo.fr
Abstract
Keywords:
1. Introduction
The study of fourth-order three-point boundary value problems (BVP) for ordinary differential equations arise in a variety of different areas of applied mathematics and physics. Various authors studied the existence of positive solutions for \(n\)th-order \(m\)-point boundary value problems using different methods, for example, fixed point theorems in cones, nonlinear alternative of Leray-Schauder, and Krasnoselskii's fixed point theorem, see [1, 2, 3, 4, 5] and the references therein.
In 2003, by using the Leray-Schauder degree theory, Liu and Ge [6] proved the existence of positive solutions for \((n-1, 1)\) three-point boundary value problems with coefficient that changes sign given as follows: \begin{gather*} u^{(n)}(t)+\lambda a(t)f(u(t))=0,\quad\text t\in(0,1),\\ u(0)=\alpha u(\eta),\quad u(1)=\beta u(\eta),\quad u^{(i)}(0)=0~~for~~i=1,2,...,n-2,\\ and~~~u^{(n-2)}(0)=\alpha u^{(n-2)}(\eta),~~~u^{(n-2)}(1)=\beta u^{(n-2)}(\eta),~~~u^{(i)}(0)=0~~for~~i=1,2,..,n-3, \end{gather*} where \(\eta\in(0,1)\), \(\alpha\geq0\), \(\beta\geq0\), and \(a: (0,1)\rightarrow \mathbb{R}\) may change sign and \(\mathbb{R}=(-\infty,\infty)\), \(f(0)>0\), \(\lambda>0\) is a parameter.
In 2005, Eloea and Ahmad [7] studied the existence of positive solutions of a nonlinear \(n\)th-order boundary value problem with nonlocal conditions as follows: \begin{gather*} u^{(n)}(t)+a(t)f(u(t))=0,\quad\text t\in(0,1),\\ u(0)=0,\quad u^{'}(0)=0,...,u^{(n-2)}(0)=0,\quad \alpha u(\eta)=u(1), \end{gather*} where \(0< \eta< 1\), \(0< \alpha\eta^{n-1}< 1\), \(f\) is either superlinear or sublinear.
In 2009, Bai et al. [8] used fixed-point theory to study the existence of positive solutions of a singular nth-order three-point boundary value problem on time scales represented as: \begin{gather*} u^{n}(t)+a(t)f(u(t))=0,\quad\text t\in(0,1),\\ u(a)=\alpha u(\eta),\quad u^{'}(a)=0,...,u^{(n-2)}(a)=0,\quad u(b)=\beta u(\eta), \end{gather*} where \(a< \eta< b\), \(0\leq a< 1\), \(0< \beta(\eta-a)^{n-1}< (1-\alpha)(b-a)^{n-1}+\alpha(\eta-a)^{n-1}\), \(f\in C([a,b]\times[0,\infty), [0,\infty))\) and \(h\in C([a,b], [0,\infty))\) may be singular at \(t=a\) and \(t=b\).
In 2004, Sun [9] studied the existence of nontrivial solution for the three-point boundary value problem: \begin{gather*} u^{''}(t)+f(t,u(t))=0,\quad\text 0\leq t\leq 1, \\ u^{'}(0)=0,\quad u(1)=\alpha u^{'}(\eta), \end{gather*} where \(\eta\in(0,1)\), \(\alpha\in\mathbb{R}\), \(f\in C([0,1]\times\mathbb{R},\mathbb{R})\). The same author in [10], studied solvability of a nonlinear second-order three-point boundary value problem: \begin{gather*} u^{''}(t)+f(t,u(t))=0,\quad\text 0\leq t\leq 1, \\ u^{'}(0)=0,\quad u(1)=\alpha u(\eta), \end{gather*} where \(\eta\in(0,1)\), \(\alpha\in\mathbb{R}\), \(\alpha\neq0\), \(f\in C([0,1]\times\mathbb{R},\mathbb{R})\).
Li and Sun [11], also used the same method to study nontrivial solution of a nonlinear second-order three-point boundary value problem: \begin{gather*} u^{''}(t)+f(t,u(t))=0,\quad\text 0\leq t\leq 1, \\ au(0)-bu^{'}(0)=0,\quad u(1)-\alpha u(\eta)=0, \end{gather*} where \(\eta\in(0,1)\), \(a,b,\alpha\in\mathbb{R}\), with \(a^{2}+b^{2}>0.\)
Motivated by the above work, we extend the results obtained for second-order boundary value problem to fourth-order boundary value problem using a different method from [7]. We prove the existence of nontrivial solution for the fourth-order three-point boundary value problem (BVP):
This paper is organized as follows: in Section 2, we present two lemmas that will be helpful in proving our main results, in Section 3, we present our main results and finally, in Section 4, we illustrated our results with examples.
2. Preliminaries
Let \(E=C[0,1]\) with the norm \(\|y\|=\sup_{t\in[0,1]}|y(t)|\) for any \(u\in E\). A solution \(u(t)\) of the BVP (1)-(2) is called nontrivial solution if \(u(t)\neq0\). To get our results, we need to the following lemma.Lemma 1. Let \(y\in C([0,1])\), \(\alpha\eta^{4}\neq1\), then the boundary value problem \begin{gather*} u^{(5)}(t)+ y(t)=0,\quad 0< t< 1, \\ u(0)=0,\quad u^{'}(0)=u^{''}(0)=u^{'''}(0)=0,\quad u(1)=\alpha u(\eta), \end{gather*} has a unique solution $$u(t)=-\frac{1}{24}\int_{0}^{t}(t-s)^{4}y(s)ds+\frac{t^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}y(s)ds- \frac{\alpha t^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{\eta}(\eta-s)^{4}y(s)ds.$$
Proof. Rewriting the differential equation as \(u^{(5)}(t)=-y(t)\), and integrating five times from \(0\) to \(1\), we obtain
Lemma 2. [1]. Let \(E\) be a Banach space and
\(\Omega\) be a bounded open subset of \(E\), \(0\in\Omega\).
\(T:\overline{\Omega}\rightarrow E\) be a completely continuous
operator. Then, either
\((i)\) there exists \(u\in \partial \Omega\) and \(\lambda>1\) such that
\(T(u)=\lambda u\), or
\((ii)\) there exists a fixed point \(u^{\ast}\in \overline {\Omega}\)
of \(T\).
3. Existence of nontrivial solution
In this section, we prove the existence of a nontrivial solution for the BVP (1)-(2). Suppose that \(f\in C([0,1]\times\mathbb{R},\mathbb{R}).\)Theorem 3. \label{thm1} Suppose that \(f(t,0)\neq 0\), \(\alpha\eta^{4}\neq1\), and there exist nonnegative functions \(k,h \in L^{1}[0,1]\), such that $$|f(t,x)|\leq k(t)|x|+h(t),\quad a.e.~~(t,x)\in [0,1]\times \mathbb{R},$$ $$\left(\frac{1}{24}+\frac{1}{24|1-\alpha\eta^{4}|}\right)\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{|\alpha|}{24|1-\alpha\eta^{4}|}\int_{0}^{\eta}(\eta-s)^{4}k(s)ds< 1.$$ Then the BVP (1)-(2) has at least one nontrivial solution \(u^{\ast}\in C[0,1].\)
Proof. Let $$M=\left(\frac{1}{24}+\frac{1}{24|1-\alpha\eta^{4}|}\right)\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{|\alpha|}{24|1-\alpha\eta^{4}|}\int_{0}^{\eta}(\eta-s)^{4}k(s)ds,$$ $$N=\left(\frac{1}{24}+\frac{1}{24|1-\alpha\eta^{4}|}\right)\int_{0}^{1}(1-s)^{4}h(s)ds+ \frac{|\alpha|}{24|1-\alpha\eta^{4}|}\int_{0}^{\eta}(\eta-s)^{4}h(s)ds.$$ Then \(M< 1\). Since \(f(t,0)\neq 0\), there exists an interval \([a,b]\subset [0,1]\) such that \(\min_{a\leq t\leq b}|f(t,0)|>0\), and as \(h(t)\geq |f(t,0)|\), a.e. \(t\in [0,1]\), we have \(N>0\). Let \(A=N(1-M)^{-1}\) and \(\Omega=\{u\in E: \|u\|< A\}\). Assume that \(u\in \partial \Omega\) and \(\lambda>1\) such that \(Tu=\lambda u\), then \begin{eqnarray*} \lambda A&=&\lambda \|u\|=\|Tu\|=\max_{0\leq t\leq 1}|(Tu)(t)|\\ &\leq& \frac{1}{24}\max_{0\leq t\leq1}\int_{0}^{t}(t-s)^{4}|f(s,u(s))|ds+\max_{0\leq t\leq1}\left|\frac{t^{4}}{24(1-\alpha\eta^{4})}\right|\int_{0}^{1}(1-s)^{4}|f(s,u(s))|ds\\ &&+\max_{0\leq t\leq1}\left|\frac{\alpha t^{4}}{24(1-\alpha\eta^{4})}\right|\int_{0}^{\eta}(\eta-s)^{4}|f(s,u(s))|ds\\ &\leq&\left(\frac{1}{24}+\frac{1}{24|1-\alpha\eta^{4}|}\right)\int_{0}^{1}(1-s)^{4}|f(s,u(s))|ds+\frac{|\alpha|}{24|1-\alpha\eta^{4}|}\int_{0}^{\eta}(\eta-s)^{4}|f(s,u(s))|ds\\ &\leq&\left(\frac{1}{24}+\frac{1}{24|1-\alpha\eta^{4}|}\right)\int_{0}^{1}(1-s)^{4}k(s)|u(s)|ds+\frac{|\alpha|}{24|1-\alpha\eta^{4}|}\int_{0}^{\eta}(\eta-s)^{4}k(s)|u(s)|ds\\ &&+\left(\frac{1}{24}+\frac{1}{24|1-\alpha\eta^{4}|}\right)\int_{0}^{1}(1-s)^{4}h(s)ds+\frac{|\alpha|}{24|1-\alpha\eta^{4}|}\int_{0}^{\eta}(\eta-s)^{4}h(s)ds\\ &=& M \|u\|+N. \end{eqnarray*} Therefore, $$\lambda \leq M+\frac{N}{A}=M+\frac{N}{N(1-M)^{-1}}=M+(1-M)=1.$$ This contradicts \(\lambda>1\). By Lemma 2, \(T\) has a fixed point \(u^{\ast}\in\overline{\Omega}\). In view of \(f(t,0)\neq0\), the BVP (1)-(2) has a nontrivial solution \(u^{\ast}\in E\). This completes the proof.
Theorem Suppose that \(f(t,0)\neq0\), \(\alpha\eta^{4}< 1\), and there exist nonnegative functions \(k,h\in L^{1}[0,1]\), such that $$|f(t,x)|\leq k(t)|x|+h(t),\quad a.e.~~(t,x)\in [0,1]\times\mathbb{R}.$$ If one of the following conditions holds:
- there exists a constant \(p>1\) such that $$\int_{0}^{1}k(s)^{p}ds< \left[\frac{24(1-\alpha\eta^{4})(1+4q)^{1/q}}{2-\alpha\eta^{4}+|\alpha|\eta^{(1+4q)/q}}\right]^{p}, \quad\frac{1}{p}+\frac{1}{q}=1;$$
- there exists a constant \(\mu>-1\) such that $$k(s)\leq \frac{(1-\alpha\eta^{4})(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{2-\alpha\eta^{4}+|\alpha|\eta^{5+\mu}}s^{\mu},\quad a.e.~~~s\in [0,1],$$ $$meas\{s\in[0,1] : k(s)< \frac{(1-\alpha\eta^{4})(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{2-\alpha\eta^{4}+|\alpha|\eta^{5+\mu}}s^{\mu}\}>0;$$
- there exists a constant \(\mu>-5\) such that $$k(s)\leq \frac{24(1-\alpha\eta^{4})(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}(1-s)^{\mu},\quad a.e.~~~s\in [0,1],$$ $$meas\left\{s\in[0,1] : k(s)< \frac{24(1-\alpha\eta^{4})(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}(1-s)^{\mu}\right\}>0;$$
- \(k(s)\) satisfies $$k(s)\leq\frac{120(1-\alpha\eta^{4})}{2-\alpha\eta^{4}+|\alpha|\eta^{5}},\quad a.e.~~~s\in [0,1], meas\left\{s\in[0,1] : k(s)< \frac{120(1-\alpha\eta^{4})}{2-\alpha\eta^{4}+|\alpha|\eta^{5}}\right\}>0,$$
Proof. Let \(M\) be defined as in the proof of Theorem 3. To prove Theorem 4, we only need to prove that \(M< 1\). Since \(\alpha\eta^{4}< 1\), we have $$M=\left(\frac{1}{24}+\frac{1}{24(1-\alpha\eta^{4})}\right)\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{\eta}(\eta-s)^{4}k(s)ds$$ $$=\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{\eta}(\eta-s)^{4}k(s)ds.~~~~\quad$$
- Using the H\"{o}lder inequality, we have \begin{eqnarray*} M&\leq&\left[\int_{0}^{1}k(s)^{p}ds\right]^{1/ p}\left\{\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\left[\int_{0}^{1}(1-s)^{4q}ds\right]^{1/ q} +\frac{|\alpha|}{24(1-\alpha\eta^{4})}\left[\int_{0}^{\eta}(\eta-s)^{4q}ds\right]^{1/q}\right\}\\ &\leq&\left[\int_{0}^{1}k(s)^{p}ds\right]^{1/ p}\left[\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}(\frac{1}{1+4q})^{1/q} +\frac{|\alpha|}{24(1-\alpha\eta^{4})}(\frac{\eta^{1+4q}}{1+4q})^{1/q}\right]\\ &<&\frac{24(1-\alpha\eta^{4})(1+4q)^{1/q}}{2-\alpha\eta^{4}+|\alpha|\eta^{(1+4q)/q}}\times \frac{2-\alpha\eta^{4}+|\alpha|\eta^{(1+4q)/q}}{24(1-\alpha\eta^{4})(1+4q)^{1/q}}\\ &=&1. \end{eqnarray*}
- Here, we have \begin{eqnarray*}M&<&\frac{(1-\alpha\eta^{4})(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{2-\alpha\eta^{4}+|\alpha|\eta^{5+\mu}}\\&&\times\left[\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}s^{\mu}ds+\frac{|\alpha|}{24(1-\alpha\eta^{4})} \int_{0}^{\eta}(\eta-s)^{4}s^{\mu}ds\right]\\ &\leq&\frac{(1-\alpha\eta^{4})(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{2-\alpha\eta^{4}+|\alpha|\eta^{5+\mu}}\left[\frac{2-\alpha\eta^{4}}{(1-\alpha\eta^{4})}\frac{1} {(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}\right.\\&&\left.+ \frac{|\alpha|}{(1-\alpha\eta^{4})}\frac{\eta^{5+\mu}}{(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}\right]\\&=&\frac{(1-\alpha\eta^{4})(1+\mu) (2+\mu)(3+\mu)(4+\mu)(5+\mu)}{2-\alpha\eta^{4}+|\alpha|\eta^{5+\mu}}. \frac{2-\alpha\eta^{4}+|\alpha|\eta^{5+\mu}}{(1-\alpha\eta^{4})(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}\\&=&1.\end{eqnarray*}
- Here, we have \begin{eqnarray*}M&<&\frac{24(1-\alpha\eta^{4})(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}\left[\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4+\mu}ds+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{\eta}(\eta-s)^{4}(1-s)^{\mu}ds\right]\\ &\leq&\frac{24(1-\alpha\eta^{4})(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}\left[\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4+\mu}ds+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4+\mu}ds\right]\\ &=&\frac{24(1-\alpha\eta^{4})(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}\left[\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}.\frac{1}{5+\mu}+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}.\frac{1}{5+\mu}\right]\\ &=&\frac{24(1-\alpha\eta^{4})(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}.\frac{2-\alpha\eta^{4}+|\alpha|}{24(1-\alpha\eta^{4})(5+\mu)}=1.\end{eqnarray*}
- Here, we have \begin{eqnarray*}M&<&\frac{120(1-\alpha\eta^{4})}{2-\alpha\eta^{4}+|\alpha|\eta^{5}}\left[\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}ds+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{\eta}(\eta-s)^{4}ds\right]\\ &=&\frac{120(1-\alpha\eta^{4})}{2-\alpha\eta^{4}+|\alpha|\eta^{5}}.\frac{2-\alpha\eta^{4}+|\alpha|\eta^{5}}{120(1-\alpha\eta^{4})}=1.\end{eqnarray*}
Theorem 5. Suppose that \(f(t,0)\neq0\), \(\alpha\eta^{4}>1\), and there exist nonnegative functions \(k,h\in L^{1}[0,1]\) such that $$|f(t,x)|\leq k(t)|x|+h(t),\quad a.e.~~(t,x)\in [0,1]\times \mathbb{R}.$$ If one of the following conditions holds:
- there exists a constant \(p>1\) such that $$\int_{0}^{1}k(s)^{p}ds< \left[\frac{24(\alpha\eta^{4}-1)(1+4q)^{1/q}}{\alpha(\eta^{4}+\eta^{(1+4q)/q})}\right]^{p}, \quad\left(\frac{1}{p}+\frac{1}{q}=1\right);$$
- there exists a constant \(\mu>-1\) such that $$k(s)\leq \frac{(\alpha\eta^{4}-1)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{\alpha(\eta^{4}+\eta^{5+\mu})}s^{\mu},\quad a.e.~~~s\in [0,1],$$ $$meas\left\{s\in[0,1] : k(s)< \frac{(\alpha\eta^{4}-1)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{\alpha(\eta^{4}+\eta^{5+\mu})}s^{\mu}\right\}>0;$$
- there exists a constant \(\mu>-5\) such that $$k(s)\leq \frac{24(\alpha\eta^{4}-1)(5+\mu)}{\alpha(\eta^{4}+1)}(1-s)^{\mu},\quad a.e.~~~s\in [0,1],$$ $$meas\{s\in[0,1] : k(s)< \frac{24(\alpha\eta^{4}-1)(5+\mu)}{\alpha(\eta^{4}+1)}(1-s)^{\mu}\}>0;$$
- \(k(s)\) satisfies $$k(s)\leq\frac{120(\alpha\eta^{4}-1)}{\alpha(\eta^{4}+\eta^{5})},\quad a.e.~~~s\in [0,1],$$ $$meas\left\{s\in[0,1] : k(s)< \frac{120(\alpha\eta^{4}-1)}{\alpha(\eta^{4}+\eta^{5})}\right\}>0,$$
Proof. Let \(M\) be defined as in the proof of Theorem 3. To prove Theorem 5, we only need to prove that \(M< 1\). Since \(\alpha\eta^{4}>1\), we have \begin{eqnarray*}M&=&\frac{\alpha\eta^{4}}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{\alpha}{24(\alpha\eta^{4}-1)}\int_{0}^{\eta}(\eta-s)^{4}k(s)ds\\ &=&\frac{\alpha}{24(\alpha\eta^{4}-1)}[\eta^{4}\int_{0}^{1}(1-s)^{4}k(s)ds+\int_{0}^{\eta}(\eta-s)^{4}k(s)ds].\end{eqnarray*}
- Using the H\"{o}lder inequality, we have \begin{eqnarray*}M&\leq&\left[\int_{0}^{1}k(s)^{p}ds\right]^{1/ p}\left\{\frac{\alpha\eta^{4}}{24\left(\alpha\eta^{4}-1\right)}\left[\int_{0}^{1}(1-s)^{4q}ds\right]^{1/q} +\frac{\alpha}{24\left(\alpha\eta^{4}-1\right)}\left[\int_{0}^{\eta}(\eta-s)^{4q}ds\right]^{1/q}\right\}\\ &\leq&\left[\int_{0}^{1}k(s)^{p}ds\right]^{1/ p}\left[\frac{\alpha\eta^{4}}{24(\alpha\eta^{4}-1)}(\frac{1}{1+4q})^{1/q} +\frac{\alpha}{24(\alpha\eta^{4}-1)}(\frac{\eta^{1+4q}}{1+4q})^{1/q}\right]\\ &<&\frac{24\left(\alpha\eta^{4}-1\right)(1+4q)^{1/q}}{\alpha(\eta^{4}+\eta^{(1+4q)/q})}\times \frac{\alpha(\eta^{4}+\eta^{(1+4q)/q})}{24(\alpha\eta^{4}-1)(1+4q)^{1/q}}=1.\end{eqnarray*}
- Here, we have \begin{eqnarray*}M&<&\frac{(\alpha\eta^{4}-1)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{\alpha(\eta^{4}+\eta^{5+\mu})}\left[\frac{\alpha\eta^{4}}{24 (\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4}s^{\mu}ds\right.\end{eqnarray*} \begin{eqnarray*} \\&&+\left.\frac{\alpha}{24(\alpha\eta^{4}-1)}\int_{0}^{\eta}(\eta-s)^{4}s^{\mu}ds\right]\\ &\leq&\frac{(\alpha\eta^{4}-1)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{\alpha(\eta^{4}+\eta^{5+\mu})}\left[\frac{\alpha\eta^{4}} {(\alpha\eta^{4}-1)}\frac{1}{(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}\right.\\&&\left.+\frac{\alpha}{(\alpha\eta^{4}-1)}\times\frac{\eta^{5+\mu}}{(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}\right]\\ &=&\frac{(\alpha\eta^{4}-1)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{\alpha(\eta^{4}+\eta^{5+\mu})}. \frac{\alpha(\eta^{4}+\eta^{5+\mu})}{(\alpha\eta^{4}-1)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}\\&=&1.\end{eqnarray*}
- Here, we have \begin{eqnarray*}M&<&\frac{24(\alpha\eta^{4}-1)(5+\mu)}{\alpha(\eta^{4}+1)}\left[\frac{\alpha\eta^{4}}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4+\mu}ds+ \frac{\alpha}{24(\alpha\eta^{4}-1)}\int_{0}^{\eta}(\eta-s)^{4}(1-s)^{\mu}ds\right]\\ &\leq&\frac{24(\alpha\eta^{4}-1)(5+\mu)}{\alpha(\eta^{4}+1)}\left[\frac{\alpha\eta^{4}}{24(\alpha(\eta^{4}-1)}\int_{0}^{1}(1-s)^{4+\mu}ds+ \frac{\alpha}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4+\mu}ds\right]\\ &=&\frac{24(\alpha\eta^{4}-1)(5+\mu)}{\alpha(\eta^{4}+1)}\left[\frac{\alpha\eta^{4}}{24(\alpha\eta^{4}-1)}.\frac{1}{5+\mu}+ \frac{\alpha}{24(\alpha\eta^{4}-1)}.\frac{1}{5+\mu}\right]\\ &=&\frac{24(\alpha\eta^{4}-1)(5+\mu)}{\alpha(\eta^{4}+1)}.\frac{\alpha(\eta^{4}+1)}{24(\alpha\eta^{4}-1)(5+\mu)}=1.\end{eqnarray*}
- Here, we have \begin{eqnarray*}M&<&\frac{120(\alpha\eta^{4}-1)}{\alpha(\eta^{4}+\eta^{5})}\left[\frac{\alpha\eta^{4}}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4}ds+ \frac{\alpha}{24(\alpha\eta^{4}-1)}\int_{0}^{\eta}(\eta-s)^{4}ds\right]\\ &=&\frac{120(\alpha\eta^{4}-1)}{\alpha(\eta^{4}+\eta^{5})}.\frac{\alpha(\eta^{4}+\eta^{5})}{120(\alpha\eta^{4}-1)}=1.\end{eqnarray*}
Corollary 6. Suppose \(f(t,0)\neq0\), \(\alpha\eta^{4}< 1\), and there exist nonnegative functions \(k, h\in L^{1}[0,1]\) such that $$|f(t,x)|\leq k(t)|x|+h(t),\quad a.e.~~(t,x)\in [0,1]\times \mathbb{R}.$$ If one of following conditions holds:
- there exists a constant \(p>1\) such that $$\int_{0}^{1}k(s)^{p}ds< \left[\frac{24(1-\alpha\eta^{4})(1+4q)^{1/q}}{2-\alpha\eta^{4}+|\alpha|}\right]^{p}; \quad\frac{1}{p}+\frac{1}{q}=1;$$
- there exists a constant \(\mu>-1\) such that $$k(s)\leq \frac{(1-\alpha\eta^{4})(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}s^{\mu},\quad a.e.~~~s\in [0,1],$$ $$meas\{s\in[0,1] : k(s)< \frac{(1-\alpha\eta^{4})(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{2-\alpha\eta^{4}+|\alpha|}s^{\mu}\}>0;$$
- \(k(s)\) satisfies $$k(s)\leq\frac{120(1-\alpha\eta^{4})}{2-\alpha\eta^{4}+|\alpha|},\quad a.e.~~~s\in [0,1],$$ $$meas\left\{s\in[0,1] : k(s)< \frac{120(1-\alpha\eta^{4})}{2-\alpha\eta^{4}+|\alpha|}\right\}>0,$$
Proof. We have \begin{eqnarray*}M&=&\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{\eta}(\eta-s)^{4}k(s)ds\\ &\leq&\frac{2-\alpha\eta^{4}}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}k(s)ds\\ &=&\frac{2-\alpha\eta^{4}+|\alpha|}{24(1-\alpha\eta^{4})}\int_{0}^{1}(1-s)^{4}k(s)ds.\end{eqnarray*} Proof of this corollary 6 is the same method in the proof Theorem 4. The proof is complete.
Corollary 7. Suppose that \(f(t,0)\neq0\), \(\alpha\eta^{4}>1\), and there exist nonnegative functions \(k,h\in L^{1}[0,1]\) such that $$|f(t,x)|\leq k(t)|x|+h(t),\quad a.e.~~(t,x)\in [0,1]\times \mathbb{R}.$$ If one of the following conditions holds:
- there exists a constant \(p>1\) such that $$\int_{0}^{1}k(s)^{p}ds< \left[\frac{24(\alpha\eta^{4}-1)(1+4q)^{1/q}}{\alpha(\eta^{4}+1)}\right]^{p}; \quad\frac{1}{p}+\frac{1}{q}=1;$$
- there exists a constant \(\mu>-1\) such that $$k(s)\leq \frac{\left(\alpha\eta^{4}-1\right)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{\alpha(\eta^{4}+1)}s^{\mu},\quad a.e.~~~s\in [0,1],$$ $$meas\left\{s\in[0,1] : k(s)< \frac{\left(\alpha\eta^{4}-1\right)(1+\mu)(2+\mu)(3+\mu)(4+\mu)(5+\mu)}{\alpha(\eta^{4}+1)}s^{\mu}\right\}>0;$$
- \(k(s)\) satisfies $$k(s)\leq\frac{120(\alpha\eta^{4}-1)}{\alpha(\eta^{4}+1)},\quad a.e.~~~s\in [0,1],$$ $$meas\left\{s\in[0,1] : k(s)< \frac{120(\alpha\eta^{4}-1)}{\alpha(\eta^{4}+1)}\right\}>0,$$
Proof. We have \begin{eqnarray*}M&=&\frac{\alpha\eta^{4}}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{\alpha}{24(\alpha\eta^{4}-1)}\int_{0}^{\eta}(\eta-s)^{4}k(s)ds\\ &\leq&\frac{\alpha\eta^{4}}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4}k(s)ds+ \frac{\alpha}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4}k(s)ds\\ &=&\frac{\alpha(\eta^{4}+1)}{24(\alpha\eta^{4}-1)}\int_{0}^{1}(1-s)^{4}k(s)ds.\end{eqnarray*} The rest procedure is the same as for Theorem 5. This completes the proof.
4. Examples
In order to illustrate the above results, we consider some examples.Example 1. Consider the following problem
Example 2. Consider the following problem
Example 3. Consider the following problem
Example 4. Consider the following problem
Example 5. Consider the following problem
Author Contributions
All authors contributed equally to the writing of this paper. All authors read and approved the final manuscript.Competing Interests
The author(s) do not have any competing interests in the manuscript.References
- Deimling, K. (1985). Nonlinear functional analysis. Springer, Berlin. [Google Scholor]
- Ji, Y., & Guo, Y. (2009). The existence of countably many positive solutions for some nonlinear nth order m-point boundary value problems. Journal of Computational and Applied Mathematics, 232(2), 187-200. [Google Scholor]
- Graef, J. R., & Moussaoui, T. (2009). A class of nth-order BVPs with nonlocal conditions. Computers & Mathematics with Applications, 58(8), 1662-1671.[Google Scholor]
- Yang, J., & Wei, Z. (2008). Positive solutions of $n$th order $m$-point boundary value problem. Applied Mathematics and Computation, 202(2), 715-720. [Google Scholor]
- Agarwal, R. P. (1979). Boundary Value Problems for Higher-Order Differntial Equations, MATSCIENCE. The institute of Mathematics Science. Madras-600020 (INDIA). [Google Scholor]
- Liu, Y., & Ge, W. (2003). Positive solutions for \((n-1,1)\) three-point boundary value problems with coefficient that changes sign. Journal of mathematical analysis and applications, 282(2), 816-825. [Google Scholor]
- Eloe, P. W., & Ahmad, B. (2005). Positive solutions of a nonlinear nth order boundary value problem with nonlocal conditions. Applied Mathematics Letters, 18(5), 521-527. [Google Scholor]
- Xie, D., Liu, Y., & Bai, C. (2009). Green's function and positive solutions of a singular nth-order three-point boundary value problem on time scales. Electronic Journal of Qualitative Theory of Differential Equations, 2009(38), 1-14. [Google Scholor]
- Sun, Y. P. (2004). Nontrivial solution for a three-point boundary-value problem. Electronic Journal of Differential Equations, 2004(111),1-10.[Google Scholor]
- Sun, Y., & Liu, L. (2004). Solvability for a nonlinear second-order three-point boundary value problem. Journal of Mathematical Analysis and Applications, 296(1), 265-275.[Google Scholor]
- Shuhong, L., & Sun, Y. P. (2007). Nontrivial solution of a nonlinear second order three-point boundaryvalue problem. Applied Mathematics-A Journal of Chinese Universities Series B, 22(1), 37-47. [Google Scholor]