Existence criterion for the solutions of fractional order p-Laplacian boundary value problems

Jafari, Hossein; Baleanu, Dumitru; Khan, Hasib; Khan, Rahmat Ali; Khan, Aziz

doi:10.1186/s13661-015-0425-2

Research
Open access
Published: 17 September 2015

Existence criterion for the solutions of fractional order p-Laplacian boundary value problems

Hossein Jafari^1,2,
Dumitru Baleanu^3,4,
Hasib Khan^5,6,
Rahmat Ali Khan⁵ &
…
Aziz Khan⁵

Boundary Value Problems volume 2015, Article number: 164 (2015) Cite this article

1591 Accesses
40 Citations
Metrics details

Abstract

The existence criterion has been extensively studied for different classes in fractional differential equations (FDEs) through different mathematical methods. The class of fractional order boundary value problems (FOBVPs) with p-Laplacian operator is one of the most popular class of the FDEs which have been recently considered by many scientists as regards the existence and uniqueness. In this scientific work our focus is on the existence and uniqueness of the FOBVP with p-Laplacian operator of the form: $D^{\gamma}(\phi_{p}(D^{\theta}z(t)))+a(t)f(z(t)) =0$, $3<{\theta}$, $\gamma\leq{4}$, $t\in[0,1]$, $z(0)=z'''(0)$, $\eta D^{\alpha}z(t)|_{t=1}= z'(0)$, $\xi z''(1)-z''(0)=0$, $0<\alpha<1$, $\phi_{p}(D^{\theta}z(t))|_{t=0}=0 =(\phi_{p}(D^{\theta}z(t)))'|_{t=0}$, $(\phi_{p}(D^{\theta} z(t)))''|_{t=1} = \frac{1}{2}(\phi_{p}(D^{\theta} z(t)))''|_{t=0}$, $(\phi_{p}(D^{\theta}z(t)))'''|_{t=0}=0$, where $0<\xi, \eta<{1}$ and $D^{\theta}$, $D^{\gamma}$, $D^{\alpha}$ are Caputo’s fractional derivatives of orders θ, γ, α, respectively. For this purpose, we apply Schauder’s fixed point theorem and the results are checked by illustrative examples.

1 Introduction

Fractional calculus has widely been studied by scientists from the era of Leibniz to the present and has drawn the attention of mathematicians, engineers, and physicists in many scientific disciplines based on mathematical modeling, and it was found that the fractional order models are more precise in comparison with integer order models and, therefore, we can see many useful fractional order models in fluid flow, viscoelasticity, signal processing, and many other fields. For instance, see [1–6].

In fractional calculus, the existence of a positive solution for FOBVP with p-Laplacian operator has extensively attracted the attention of the scientific community. This side of the fractional calculus has a wide range of applications in day life problems and these were investigated for the existence of solutions by different mathematical tools. For instance, Lv [7], has studied existence results for m-point FOBVP with p-Laplacian operator with the help of a monotone iterative technique and produced interesting results which were examined by two examples. Prasad and Krushna [8] studied FOBVPs with p-Laplacian operator with the help of the Krasnosel’skii and five functional fixed point theorems and checked their results by examples. Yuan and Yang [9] studied the existence of a positive solution for a q-FOBVP with a p-Laplacian operator using the upper and lower solution method through Schauder’s fixed point theorem and the results were examined by examples.

Some of the interesting results in the existence of positive solution for FOBVP with p-Laplacian operator which raised our attention toward this project are, for instance, that Zhang et al. [10] has contributed for positive solutions of an FOBVP with p-Laplacian

$$ \begin{aligned} &\bigl(\phi_{p}\bigl(z'\bigr) \bigr)' = k\bigl(\tau,z,z'\bigr), \quad \tau\in[0,T], \\ &z(T) = z(0),\qquad z'(T)= z'(0), \end{aligned} $$

(1)

with the help of degree theory, and they also used the upper and lower solution method for this work. Xu and Xu in [11] investigated the p-Laplacian equation for sign changing equations of the form

$$ \begin{aligned} &\bigl(\phi_{p}\bigl(z'(\tau)\bigr) \bigr)' = -f\bigl(\tau,z,z'\bigr), \quad \tau\in(0,1), \\ &z(0) = 0=z(1), \end{aligned} $$

(2)

using the method of upper and lower solution method with the help of Leray-Schauder degree theory. Wang in [12] considered three solutions of

$$ \begin{aligned} &\bigl(\phi_{p}\bigl(z'(\tau)\bigr) \bigr)'+m(\tau)f\bigl(\tau,z,z'\bigr) = 0, \quad 0< \tau< \infty, \\ &z(0) = 0,\qquad \lim_{\tau\rightarrow{+\infty}}z=0. \end{aligned} $$

(3)

In this paper we consider the FOBVP with p-Laplacian of the form

$$\begin{aligned}& D^{\gamma}\bigl(\phi_{p}\bigl(D^{\theta}z(t) \bigr)\bigr)+a(t)f\bigl(z(t)\bigr) = 0, \quad 3< {\theta}, \gamma \leq{4}, t \in[0,1], \\& z(0)=z'''(0),\qquad \eta D^{\alpha}z(t)|_{t=1} = z'(0),\qquad \xi z''(1)-z''(0)=0,\quad 0< \alpha< 1, \\& \phi_{p}\bigl(D^{\theta}z(t)\bigr)|_{t=0}=0 = \bigl( \phi_{p}\bigl(D^{\theta}z(t)\bigr)\bigr)'|_{t=0}, \\& \bigl(\phi_{p}\bigl(D^{\theta} z(t)\bigr)\bigr)''|_{t=1} = \frac{1}{2}\bigl(\phi_{p}\bigl(D^{\theta} z(t)\bigr) \bigr)''|_{t=0}, \\& \bigl(\phi_{p}\bigl(D^{\theta}z(t)\bigr)\bigr)'''|_{t=0} = 0, \end{aligned}$$

(4)

where $D^{\theta}$, $D^{\gamma}$, and $D^{\alpha}$ are Caputo’s fractional derivatives of fractional order θ, γ, α where $\theta, \gamma\in(3,4]$, and $\alpha\in(0,1)$. $\phi_{p}(s)=|s|^{p-2}s$, $p>1$, $\phi_{p}^{-1}=\phi_{q}$, $\frac{1}{p}+\frac{1}{q}=1$. We recall some basic definitions and results. For $\alpha>0$, choose $n=[\alpha]+1$ in the case α is not an integer and $n=\alpha$ in the case α is an integer. We recall the following definitions of a fractional order integral and a fractional order derivative in Caputo’s sense, and some basic results of fractional calculus [2, 13].

Definition 1

[13]

For a function $k:(0,\infty)\rightarrow R$ and $\gamma>0$, fractional integral of order γis defined by

$$ I^{\gamma}k(\tau)=\frac{1}{\Gamma(\gamma)}\int_{0}^{\tau}( \tau-s)^{\gamma -1} k(s) \, ds, $$

(5)

with the condition that the integral converges.

Definition 2

[13]

For $\gamma>0$ the left Caputo fractional derivative of order γ is defined by

$$ \bigl(D^{\gamma}\bigr)h\bigl(z(t)\bigr)=\frac{1}{\Gamma(n-\gamma)}\int ^{t}_{a} (t-x)^{n-\gamma-1}f^{(n)}(x)\, dx, $$

(6)

where n is such that $n-1<\gamma<n$.

Lemma 3

[2]

For $\mu, \beta>{0}$, the following relation holds: $D^{\mu}t^{\nu}=\frac{\Gamma(\nu+1)}{\Gamma(\nu+1-\mu)}t^{\nu-\mu-1}$, $\nu>{n}$ and $D^{\mu}t^{l}=0$, for $l=0,1,2,\ldots,n-1$.

Lemma 4

For $\mathcal{H}(t)\in{C(0,1)}$, the solution of the homogeneous FDE $D_{0^{+}}^{\omega}\mathcal{H}(t)=0 $ is

$$ \mathcal{H}(t)=k_{1}+k_{2}t+k_{3}t^{2}+ \cdots+k_{n}t^{n-1},\quad k_{i}\in {R},i=1,2,3, \ldots,n. $$

(7)

Definition 5

[14]

A cone P is solid in a real Banach space X if its interior is non-empty.

Definition 6

[14]

Let P be a solid cone in a real Banach space X, $T:P^{0}\rightarrow P^{0}$ be an operator and $0<\alpha<1$. Then T is called θ-concave operator if $T(ku)\geq{k^{\alpha}}T(u)$ for any $0< k<1$ and $u\in{P^{0}}$.

Lemma 7

[14]

Assume that P is a normal solid cone in a real Banach space X, $0<\alpha<1$, and $T:P^{0}\rightarrow{P^{0}}$ is a α-concave increasing operator. Then T has only one fixed point in $P^{0}$.

2 Main results

Lemma 8

For $z(t)\in C[0,1]$, the FOBVP

$$\begin{aligned}& D^{\theta}z(t)=h(t),\quad 3< {\theta}\leq{4}, \end{aligned}$$

(8)

$$\begin{aligned}& z(0)=z'''(0),\qquad \eta D^{\alpha}z(1)=z'(0),\qquad \xi z''(1)-z''(0)=0, \quad 0< \alpha< 1, \end{aligned}$$

(9)

has a solution of the form

$$ z(t)=\int_{0}^{1}G(t,s)h(t)\, ds, $$

(10)

where

$$ G(t,s)= \textstyle\begin{cases} \frac{t\eta}{1-\frac{\eta}{\Gamma(2-\alpha)}} [\frac{(1-s)^{\theta -\alpha-1}}{\Gamma(\theta-\alpha)}+\frac{\xi}{(1-\xi)\Gamma(3-\alpha )}\frac{(1-s)^{\theta-3}}{\Gamma(\theta-2)} ] \\ \quad +\frac{t^{2}\xi}{2(1-\xi)}\frac{(1-s)^{\theta-3}}{\Gamma(\theta -2)}+\frac{1}{\Gamma(\theta)}(t-s)^{\theta-1},& 0< {s}\leq{t}< {1}, \\ \frac{t\eta}{1-\frac{\eta}{\Gamma(2-\alpha)}} [\frac{(1-s)^{\theta -\alpha-1}}{\Gamma(\theta-\alpha)}+\frac{\xi}{(1-\xi)\Gamma(3-\alpha )}\frac{(1-s)^{\theta-3}}{\Gamma(\theta-2)} ] \\ \quad {}+\frac {t^{2}\xi}{2(1-\xi)}\frac{(1-s)^{\theta-3}}{\Gamma(\theta-2)}, &0< {t}\leq {s}< {1}. \end{cases} $$

(11)

Proof

Applying the operator $I^{\alpha}$ on the differential equation in (4) and using Lemma 4, we obtain

$$ z(t)=I^{\theta} h(t)+c_{1}+c_{2}t+c_{3}t^{2}+c_{4}t^{3}. $$

(12)

Using boundary conditions (9) for the values of $c_{1}$, $c_{2}$, $c_{3}$, $c_{4}$, $z(0)=0=z'''(0)$ yield to $c_{1}=0=c_{4}$, and by $\xi z''(1)-z''(0)=0$, we have $c_{3}=\frac{\xi}{2(1-\xi)}I^{\theta-2}h(1)$. Using $\eta D^{\alpha }z(1)=z'(0)$, we obtain $c_{2}=\frac{\eta}{1-\frac{\eta}{\Gamma(2-\alpha)}} [I^{\theta-\alpha }h(1)+\frac{\xi}{(1-\xi)\Gamma(3-\alpha)}I^{\theta-2}h(1) ]$. Substituting the values of $c_{1}$, $c_{2}$, $c_{3}$, $c_{4}$, in (12), we get

$$\begin{aligned} z(t) =&I^{\theta} h(t)+\frac{t\eta}{1-\frac{\eta}{\Gamma(2-\alpha )}} \biggl[I^{\theta-\alpha}h(1)+\frac{\xi}{(1-\xi)\Gamma(3-\alpha )}I^{\theta-2}h(1) \biggr] \\ &{}+\frac{t^{2}\xi}{2(1-\xi)}I^{\theta -2}h(1). \end{aligned}$$

(13)

The integral form is given as

$$\begin{aligned} z(t) =&\int_{0}^{t} \frac{(t-s)^{\theta-1}h(s)\, ds}{\Gamma(\theta)} +\frac{t^{2}\xi}{2(1-\xi)}\int_{0}^{1} \frac{(1-s)^{\theta-3}h(s)\, ds}{\Gamma (\theta-2)} \\ &{}+\frac{t\eta}{1-\frac{\eta}{\Gamma(2-\alpha)}} \biggl[ \int_{0}^{1} \frac{(1-s)^{\theta-\alpha-1}h(s)\, ds}{\Gamma(\theta-\alpha )} \\ &{}+\frac{\xi}{(1-\xi)\Gamma(3-\alpha)}\int_{0}^{1} \frac {(1-s)^{\theta-3}h(s)\, ds}{\Gamma(\theta-2)} \biggr] =\int_{0}^{1}G(t,s)h(s)\, ds. \end{aligned}$$

(14)

□

Lemma 9

Let $3<{\theta}, \gamma\leq{4}$. For $z(t)\in{C [0,1]}$, the FOBVP with p-Laplacian

$$\begin{aligned}& D^{\gamma}\bigl(\phi_{p}\bigl(D^{\theta}z(t) \bigr)\bigr)+a(t)f\bigl(z(t)\bigr) = 0, \quad 3< {\theta}, \gamma \leq{4}, t \in[0,1], \\& z(0)=z'''(0), \qquad \eta D^{\alpha}z(t)|_{t=1} = z'(0), \qquad \xi z''(1)-z''(0)=0,\quad 0< \alpha< 1, \\& \phi_{p}\bigl(D^{\theta}z(t)\bigr)|_{t=0}=0 = \bigl( \phi_{p}\bigl(D^{\theta}z(t)\bigr)\bigr)'|_{t=0}, \\& \bigl(\phi_{p}\bigl(D^{\theta} z(t)\bigr)\bigr)''|_{t=1} = \frac{1}{2}\bigl(\phi_{p}\bigl(D^{\theta} z(t)\bigr) \bigr)''|_{t=0}, \\& \bigl(\phi_{p}\bigl(D^{\theta}z(t)\bigr)\bigr)'''|_{t=0} = 0, \end{aligned}$$

(15)

has a solution of the form

$$ z(t)=\int_{0}^{1}G(t,s)\phi_{q}\biggl( \int_{0}^{1}\mathcal{H}(s,x)a(x)f\bigl(z(x)\bigr)\, dx\biggr)\, ds, $$

(16)

where

$$ \mathcal{H}(t,x) = \textstyle\begin{cases} -\frac{(t-x)^{\gamma-1}}{\Gamma\gamma}+\frac {t^{2}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3},& 0< {x}\leq{t}< {1}, \\ \frac{t^{2}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3}, &0< {t}\leq {x}< {1}, \end{cases} $$

(17)

and $G(t,s)$ is given by (11).

Applying the integral $I^{\gamma}$ on the differential equation in (15) and using Lemma 9, we obtain

$$ \phi_{p}\bigl(D^{\theta}z(t)\bigr)=-I^{\gamma}a(t)f \bigl(z(t)\bigr)+c_{1}+c_{2}t+c_{3}t^{2}+c_{4}t^{3}. $$

(18)

The boundary conditions $\phi_{p}(D^{\theta}z(0))=(\phi_{p}(D^{\theta}z(0)))'=(\phi_{p}(D^{\alpha}z(0)))'''=0$ lead to $c_{1}=c_{2}=c_{4}=0$. From (18) and $c_{1}=c_{2}=c_{4}=0$, we deduce

$$ \bigl(\phi_{p}\bigl(D^{\theta}z(t)\bigr)\bigr)''=-I^{\gamma-2}a(t)f \bigl(z(t)\bigr)+2c_{3}, $$

(19)

and the boundary condition $(\phi_{p}(D^{\theta}z(1)))''=\frac{1}{2}(\phi_{p}(D^{\theta}z(0)))''$ yield $c_{3}=\frac{1}{\Gamma(\gamma-2)} \int_{0}^{1}(1-x)^{\gamma-3} a(x)f(z(x))\, dx$. Consequently, (18) takes the form

$$\begin{aligned} \phi_{p}\bigl(D^{\theta}z(t)\bigr) =&-\frac{1}{\Gamma(\gamma)}\int _{0}^{1}(t-x)^{\gamma -1}a(x)f\bigl(z(x)\bigr)\, dx \\ &{}+\frac{t^{2}}{\Gamma(\gamma-2)}\int_{0}^{1}(1-x)^{\gamma-3}a(x)f \bigl(z(x)\bigr)\, dx \\ =&\int_{0}^{1}\mathcal{H}(t,x)a(x)f\bigl(z(x) \bigr)\, dx. \end{aligned}$$

(20)

The boundary value problem (15) reduces to the following problem:

$$ \begin{aligned} &D^{\alpha}z(t)=\phi_{q}\biggl(\int _{0}^{1}\mathcal{H}(t,x)a(x)f\bigl(z(x)\bigr)\, dx \biggr), \\ &z(0)=z'''(0), \qquad \eta D^{\alpha}z(1)= y'(0), \qquad \xi z''(1)-z''(0)=0, \quad 0< \alpha< 1, \end{aligned} $$

(21)

which, in view of Lemma 8, yields the required result,

$$ z(t)=\int_{0}^{1}G(t,s)\phi_{q}\biggl( \int_{0}^{1}\mathcal{H}(s,x)a(x)f\bigl(z(x)\bigr)\, dx\biggr)\, ds. $$

(22)

Lemma 10

Let $3< \gamma\leq{4}$. The Green’s function $\mathcal{H}(t,x)$ is a continuous function and satisfies

(A)
$\mathcal{H}(t,x)\geq0$, $\mathcal{H}(t,x)\leq\mathcal{H}(1,x)$, for $t,x\in(0,1]$,
(B)
$\mathcal{H}(t,x) \geq t^{\gamma-1 }\mathcal{H}(1,x)$ for $t,x \in(0,1]$.

The continuity of $\mathcal{H}(t,x)$ is ensured by its definition. For (A), considering the case when $0<{x}\leq{t}\leq1$, we have

$$\begin{aligned} \mathcal{H}(t,x) =&-\frac{(t-x)^{\gamma-1}}{\Gamma(\gamma)}+\frac {t^{2}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3} \\ =&-\frac{t^{\gamma-1}(1-\frac{x}{t})^{\gamma-1}}{\Gamma(\gamma)}+\frac {t^{2}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3} \\ \geq&-\frac{t^{\gamma-1}(1-x)^{\gamma-1}}{\Gamma(\gamma)}+\frac {t^{\gamma-1}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3} \\ \geq& \frac{t^{\gamma-1}(1-x)^{\gamma-1}}{\Gamma(\gamma)\Gamma(\gamma -2)} \bigl[\Gamma(\gamma)-\Gamma(\gamma-2) \bigr]>0. \end{aligned}$$

(23)

In the case $0< t\leq x\leq1$, the $\mathcal{H}(t,s)>0$ is obvious. Now for $\mathcal{H}(t,x)\leq\mathcal{H}(1,x)$, for $t,x\in(0,1]$, we have

$$ \frac{\partial}{\partial t}\mathcal{H}(t,x)= \textstyle\begin{cases} -\frac{(t-x)^{\gamma-2}}{\Gamma(\gamma-1)}+2\frac{t}{\Gamma(\gamma -2)}(1-x)^{\gamma-3},& 0< {x}\leq{t}\leq{1}, \\ \frac{2t}{\Gamma(\gamma-2)}(1-x)^{\gamma-3},& 0< {t}\leq{x}\leq{1}. \end{cases} $$

(24)

For $x, t \in(0,1]$, such that $0< x\leq t\leq1$, from (24), we deduce

$$\begin{aligned} \frac{\partial}{\partial t}\mathcal{H}(t,x) =&-\frac{(t-x)^{\gamma -2}}{\Gamma(\gamma-1)}+ \frac{2t}{\Gamma(\gamma-2)}(1-x)^{\gamma -3} \\ =&-\frac{t^{\gamma-2}(1-\frac{x}{t})^{\gamma-2}}{\Gamma(\gamma -1)}+\frac{2t}{\Gamma(\gamma-2)}(1-x)^{\gamma-3} \\ \geq& -\frac{t^{\gamma-2}(1-x)^{\gamma-2}}{\Gamma(\gamma-1)}+\frac {2t^{\gamma-2}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3} \\ \geq& \frac{t^{\gamma-2}(1-x)^{\gamma-2}}{\Gamma(\gamma-1)\Gamma(\gamma -2)} \bigl[2\Gamma(\gamma-1)-\Gamma(\gamma-2) \bigr]\geq0, \end{aligned}$$

(25)

from (25), we have $\frac{\partial}{\partial t}\mathcal {H}(t,x)\geq0$. In the case $0< t\leq x \leq1$, (24) implies that the relation $\frac{\partial}{\partial t}\mathcal{H}(t,x)\geq0$ is obvious, which implies that $\mathcal{H}(t,x)$ is an increasing function w.r.t. t. Hence $\mathcal{H}(t,x)\leq\mathcal{H}(1,x)$.

Now for part (B), using (17) in the case $0< x\leq t\leq1$, we proceed thus:

$$\begin{aligned} \frac{\mathcal{H}(t,x)}{\mathcal{H}(1,x)} =&\frac{\frac{-(t-x)^{\gamma -1}}{\Gamma(\gamma)}+\frac{t^{2}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3}}{\frac {-(1-x)^{\gamma-1}}{\Gamma(\gamma)}+\frac{1}{\Gamma(\gamma -2)}(1-x)^{\gamma-3}} \\ =& \frac{\frac{-t^{\gamma-1}(1-\frac{x}{t})^{\gamma-1}}{\Gamma(\gamma )}+\frac{t^{2}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3}}{\frac{-(1-x)^{\gamma -1}}{\Gamma(\gamma)}+\frac{1}{\Gamma(\gamma-2)}(1-x)^{\gamma-3}} \\ \geq&\frac{\frac{-t^{\gamma-1}(1-x)^{\gamma-1}}{\Gamma(\gamma)}+\frac {t^{\gamma-1}}{\Gamma(\gamma-2)}(1-x)^{\gamma-3}}{\frac{-(1-x)^{\gamma -1}}{\Gamma(\gamma)}+\frac{1}{\Gamma(\gamma-2)}(1-x)^{\gamma -3}} \\ =&t^{\gamma-1} \biggl[\frac{\frac{-(1-x)^{\gamma-1}}{\Gamma(\gamma )}+\frac{1}{\Gamma(\gamma-2)}(1-x)^{\gamma-3}}{\frac{-(1-x)^{\gamma -1}}{\Gamma(\gamma)}+\frac{1}{\Gamma(\gamma-2)}(1-x)^{\gamma-3}} \biggr]=t^{\gamma-1}. \end{aligned}$$

(26)

We can also prove the result for the case of $0< t\leq x\leq1$, this completes the proof.

Assume that the following hold:

(J₁):: $0<\int_{0}^{1}\mathcal{H}(1,x)a(x)\, dx<+\infty$.
(J₂):: There exist $0<\delta<1$ and $\rho>0$ such that $f(x)\leq\delta L \phi_{p}(x)$, for $0\leq x \leq\rho$, where $0< L\leq(\phi_{p}(\varpi)\delta\int_{0}^{1}\mathcal{H}(1,x)a(x)\, dx)^{-1}$.
(J₃):: There exists $b>0$, such that $f(x)\leq M \phi_{p}(x)$, for $u>b$, $0< M<( \phi_{p}(\varpi2^{q-1})\int_{0}^{1}\mathcal{H}(1,x) a(x)\, dx)^{-1}$.
(J₄):: $f(z)$ is non-decreasing with respect to z.
(J₅):: There exists $0\leq\beta<1$ such that $f(Kz)\geq(\phi_{p}(K))^{\beta}f(z)$, for any $0\leq k<1$ and $0< z<+\infty$.

2.1 Existence and uniqueness of solutions

Theorem 11

Under the assumptions (J₁) and (J₂), the FOBVP (4) has at least one positive solution.

Proof

Define $K_{1}=\{z\in{C [0,1]}:0\leq z(t) \leq\rho\mbox{ on } [0,1]\}$ a closed convex set [15]. Define an operator $\mathcal{T}:K_{1}\rightarrow C[0,1]$ by

$$ \mathcal{T}z(t)=\int_{0}^{1}G(t,s) \phi_{q}\biggl(\int_{0}^{1} \mathcal{H}(s,x)a(x)f\bigl(z(x)\bigr)\, dx\biggr)\, ds. $$

(27)

By Lemma 9, $z(t)$ is a solution of the FOBVP with p-Laplacian operator (4) if and only if $z(t)$ is a fixed point of $\mathcal{T}$. The compactness of the operator $\mathcal{T}$ can easily be shown. Now consider

$$\begin{aligned} \int_{0}^{1}G(t,s)\,ds =& \frac{\int_{0}^{t}(t-s)^{\theta-1}\,ds}{\Gamma(\theta)}+ \frac{t\eta}{1-\frac {\eta}{\Gamma(2-\alpha)}} \biggl[\frac{\int_{0}^{1}(1-s)^{\theta-\alpha -1}\,ds}{\Gamma(\theta-\alpha)} \\ &{}+ \frac{\xi\int_{0}^{1}(1-s)^{\theta-3}\,ds}{(1-\xi)\Gamma(3-\alpha)\Gamma (\theta-2)}\biggr]+\frac{t^{2}\xi}{2(1-\xi)}\frac{\int_{0}^{1}(1-s)^{\theta -3}\,ds}{\Gamma(\theta-2)} \\ =&\frac{(t-s)^{\theta}|_{t}^{0}}{\Gamma(\theta+1)}+\frac{t\eta}{1-\frac {\eta}{\Gamma(2-\alpha)}} \biggl[\frac{(1-s)^{\theta-\alpha}|_{1}^{0}}{\Gamma (\theta-\alpha+1)} \\ &{}+\frac{\xi}{(1-\xi)\Gamma(3-\alpha)}\frac {(1-s)^{\theta-2}|_{1}^{0}}{\Gamma(\theta-1)}\biggr]+\frac{t^{2}\xi}{2(1-\xi)} \frac {(1-s)^{\theta-2}|_{1}^{0}}{\Gamma(\theta-1)} \\ =&\frac{t^{\theta}}{\Gamma(\theta+1)}+\frac{t\eta}{1-\frac{\eta}{\Gamma (2-\alpha)}} \biggl[\frac{1}{\Gamma(\theta-\alpha+1)} \\ +&\frac{\xi }{(1-\xi)\Gamma(3-\alpha)}\frac{1}{\Gamma(\theta-1)} \biggr] +\frac{t^{2}\xi }{2(1-\xi)} \frac{1}{\Gamma(\theta-1)} \\ \leq& \frac{1}{\Gamma(\theta+1)}+\frac{ \eta}{1-\frac{\eta}{\Gamma (2-\alpha)}}\biggl[\frac{1}{\Gamma(\theta-\alpha+1)} \\ +&\frac{\xi }{(1-\xi)\Gamma(3-\alpha)}\frac{1}{\Gamma(\theta-1)}\biggr] +\frac{ \xi }{2(1-\xi)} \frac{1}{\Gamma(\theta-1)} \\ =&\varpi, \end{aligned}$$

(28)

where $\varpi=\frac{1}{\Gamma(\theta+1)}+\frac{ \eta}{1-\frac{\eta }{\Gamma(2-\alpha)}} [\frac{1}{\Gamma(\theta-\alpha+1)}+\frac{\xi }{(1-\xi)\Gamma(3-\alpha)}\frac{1}{\Gamma(\theta-1)} ] +\frac{\xi }{2(1-\xi)}\frac{1}{\Gamma(\theta-1)}$. For any $y\in K_{1}$, using (J₂) and Lemma 10, we obtain

$$\begin{aligned} \mathcal{T}\bigl(z(t)\bigr) =&\int_{0}^{1} G(t,s) \phi_{q}\biggl(\int_{0}^{1}\mathcal {H}(s,x)a(x)f\bigl(z(x)\, dx\bigr)\biggr)\, ds \\ \leq&\int_{0}^{1}G(t,s)\phi_{q}\biggl( \int_{0}^{1}\mathcal{H}(1,x)a(x)L\delta\phi _{p}(\rho)\, dx\biggr)\, ds \\ \leq& \varpi\phi_{q}\biggl(\int_{0}^{1} \mathcal{H}(1,x)a(x)L\delta\phi_{p}(\rho )\, dx\biggr) \\ =&\varpi\phi_{q}\biggl(L\delta\int_{0}^{1} \mathcal{H}(1,x)a(x)\, dx\biggr)\rho\leq \rho, \end{aligned}$$

(29)

which implies $\mathcal{T}(K_{1})\subseteq{K_{1}}$. By Schauder’s fixed point theorem $\mathcal{T}$ has a fixed point in $K_{1}$. □

Theorem 12

Under the assumptions (J₁), (J₃) the FOBVP with p-Laplacian operator (4) has at least one positive solution.

Proof

Let $b>0$ as given in (J₃). Define $\mathcal{F}^{*}=\max_{0\leq{x}\leq{b}}f(x)$, then $\mathcal{F}^{*}\geq f(x)$ for $0\leq{x}\leq{b}$. In view of (J₃), we have

$$ \varpi_{1}2^{q-1}\phi_{q}(M)\phi_{q} \biggl(\int_{0}^{1}\mathcal{H}(1,x)a(x)\, dx \biggr)< 1. $$

(30)

Choose $b^{*}>b$ large enough such that

$$ \varpi_{1}2^{q-1}\bigl(\phi_{q} \bigl(\mathcal{F}^{*}\bigr)+\phi_{q}(M)b^{*}\bigr)\phi_{q} \biggl(\int_{0}^{1}\mathcal{H}(1,x)a(x)\, dx \biggr)< b^{*}. $$

(31)

Define $K_{2}=\{z(t)\in C [0,1]: 0\leq z(t)\leq{b^{*}}\mbox{ on } [0,1]\}$, $\Omega_{1}=\{t\in[0,1]:0\leq{z(t)\leq{b}}\}$, $\Omega_{2}=\{ t\in [0,1]:b<{z(t)\leq{b^{*}}}\}$. Then $\Omega_{1}\cup{\Omega_{2}}=[0,1]$ and $\Omega_{1}\cap{\Omega_{2}}=\varphi$. For $z\in{K_{1}}$, (J₃) implies $f(z(t))\leq{M}\phi_{p}(z(t))\leq{M\phi_{p}(b^{*})}$ for $t\in{\Omega_{2}}$ and

$$\begin{aligned} 0\leq\mathcal{T}\bigl(z(t)\bigr) =&\int_{0}^{1}G(t,s) \phi_{q}\biggl(\int_{0}^{1}\mathcal {H}(s,x)a(x)f\bigl(z(x)\bigr)\,dx\biggr)\,ds \\ \leq&\varpi\phi_{q}\biggl(\int_{S_{1}} \mathcal{H}(1,x)a(x)f\bigl(y(x)\bigr)\,dx+\int_{S_{2}} \mathcal{H}(1,x)a(x)f\bigl(z(x)\bigr)\,dx\biggr) \\ \leq&\varpi\phi_{q}\biggl(\mathcal{F}^{*}\int_{S_{1}} \mathcal{H}(1,x)a(x)\,dx+M\phi _{p}\bigl(b^{*}\bigr)\int _{S_{2}}\mathcal{H}(1,x)a(x)\,dx\biggr) \\ \leq&\varpi\phi_{q}\bigl(\mathcal{F}^{*}+M\phi_{p}\bigl(b^{*} \bigr)\bigr)\phi_{q}\biggl(\int_{0}^{1} \mathcal {H}(1,x)a(x)\,dx\biggr). \end{aligned}$$

(32)

From (31) and using the inequality $(a+b)^{r}\leq{2^{r}}(a^{r}+b^{r})$ for any $a,b,r>0$, with (32) we have

$$ 0\leq\mathcal{T}z(t)\leq\varpi_{1}2^{q-1}\bigl( \phi_{q}\bigl(\mathcal{F}^{*}\bigr)+\phi _{q}(M)b^{*}\bigr) \phi_{q}\biggl(\int_{0}^{1} \mathcal{H}(1,x)a(x)\, dx\biggr)\leq{b^{*}}, $$

(33)

thus $\mathcal{T}(K_{2})\subseteq{K_{2}}$. Hence by Schauder’s fixed point theorem $\mathcal{T}$ has a fixed point $z\in{K_{2}}$, therefore, the FOBVP with p-Laplacian operator (4) has at least one positive solution in $K_{2}$. □

Theorem 13

Assume that (J₁), (J₄), (J₅) hold. Then the FOBVP with p-Laplacian operator (4) has a unique positive solution.

Proof

Consider the set $\Lambda=\{z(t)\in C[0,1]:z(t)\geq0 \mbox{ on }[0,1]\}$, where Λ is a normal solid cone in $C[0,1]$ with $\Lambda^{0}=\{z(t)\in C[0,1]:z(t)>0 \mbox{ on }[0,1]\}$. Let $\mathcal{T}:\Lambda^{0}\rightarrow C[0,1]$ be defined by (27), we prove that $\mathcal{T}$ is a θ-concave and increasing operator. For $z_{1}, z_{2}\in\Lambda^{0}$ with $z_{1}\geq z_{2}$ the assumption (J₄) implies that the operator $\mathcal{T}$ is an increasing operator, i.e., $\mathcal{T}(z_{1}(t))\geq\mathcal {T}(z_{2}(t))$ on $t\in[0,1]$. With the help of $f(kz)\geq\phi_{p}(k^{\alpha})f(z)$, we have

$$\begin{aligned} \mathcal{T}\bigl(kz(t)\bigr) \geq& \int_{0}^{1} G(t,s)\phi_{q}\biggl(\int_{0}^{1}H(t,x) \phi _{p}\bigl(k^{\alpha}\bigr)a(x)f\bigl(z(x)\bigr)\, dx\biggr) \, ds \\ =&k^{\alpha}\int_{0}^{1}G(t,s) \phi_{q}\biggl(\int_{0}^{1}H(t,x)a(x)f \bigl(z(x)\bigr)\, dx\biggr)\, ds \\ =&k^{\alpha}\mathcal{T}\bigl(z(t)\bigr), \end{aligned}$$

(34)

which implies that $\mathcal{T}$ is α-concave operator and with the help of Lemma 7, the operator $\mathcal{T}$ has a unique fixed point which is the unique positive solution of the FOBVP with p-Laplacian operator (4) in $\Lambda^{0}$. □

3 Examples

Example 1

Consider the following boundary value problem:

$$ \begin{aligned} &D^{3.5}\bigl(\phi_{p} \bigl(D^{3.5}z(t)\bigr)\bigr)+tz(t)=0, \\ &z(0)=0=z'''(0),\qquad \frac{1}{2}D^{0.5} z(t)|_{t=1}-z'(0)=0,\qquad \frac {1}{2}z''(1)-z''(0)=0, \\ &\phi_{p}\bigl(D^{3.5}z(t)\bigr)|_{t=0}=0=\bigl( \phi_{p}\bigl(D^{3.5}z(t)\bigr)\bigr)'|_{t=0}, \\ &\bigl(\phi_{p}\bigl(D^{3.5}z(t)\bigr)\bigr)''|_{t=1}= \frac{1}{2} \bigl(\phi_{p}\bigl(D^{3.5}z(t)\bigr) \bigr)'',\qquad \bigl(\phi_{p} \bigl(D^{3.5}z(t)\bigr)\bigr)''|_{t=0}=0. \end{aligned} $$

(35)

Here we have $\alpha= \beta=3.5$, $\alpha=0.5$, $\xi=\gamma=\frac{1}{2}$, $a(t)=t$, $f(z(t))=z(t)$. By simple computation, we obtain $0< L\leq{1.9092}$, choose $L=1.5$, $\delta=1$, $p=2$, and then the conditions (J₁) and (J₂) are satisfied. Hence, by Theorem 11, the FOBVP with p-Laplacian operator (35) has at least one positive solution.

Example 2

For the following boundary value problem:

$$ \begin{aligned} &D^{3.5}\bigl(\phi_{p} \bigl(D^{3.5}z(t)\bigr)\bigr)+t\sqrt[3]{z}(t)=0, \\ &z(0)=0=z'''(0),\qquad 0.1D^{0.5} z(t)|_{t=1}-z'(0)=0,\qquad 0.1 z''(1)-z''(0)=0, \\ &\phi_{p}\bigl(D^{3.5}z(t)\bigr)|_{t=0}=0=\bigl( \phi_{p}\bigl(D^{3.5}z(t)\bigr)\bigr)'|_{t=0}, \\ &\bigl(\phi_{p}\bigl(D^{3.5}z(t)\bigr)\bigr)''|_{t=1}= \frac{1}{2} \bigl(\phi_{p}\bigl(D^{3.5}z(t)\bigr) \bigr)'',\qquad \bigl(\phi_{p} \bigl(D^{3.5}z(t)\bigr)\bigr)''|_{t=0}=0, \end{aligned} $$

(36)

we have $\alpha=\beta=3.5$, $\xi=\eta=0.1$, $a(t)=t$, $f(u(t))=\sqrt[3]{u}(t)$ and by simple computation we get $M<{4.4792}$ and thus by choosing $M=4.00$, $b=1$, and $p=q=2$, we see that (36) satisfy (J₁) and (J₃). Hence by Theorem 12, the FOBVP with p-Laplacian operator (36) has at least one positive solution.

Example 3

The uniqueness of the solution for FOBVP with the p-Laplacian operator; we have

$$ \begin{aligned} &D^{3.5}\bigl(\phi_{p} \bigl(D^{3.5}z(t)\bigr)\bigr)+t z(t)=0, \\ &z(0)=0=z'''(0),\qquad \frac{1}{3}D^{0.5} z(t)|_{t=1}-z'(0)=0, \qquad \frac {1}{3}z''(1)-z''(0)=0, \\ &\phi_{p}\bigl(D^{3.5}z(t)\bigr)|_{t=0}=0=\bigl( \phi_{p}\bigl(D^{3.5}z(t)\bigr)\bigr)'|_{t=0}, \\ &\bigl(\phi_{p}\bigl(D^{3.5}z(t)\bigr)\bigr)''|_{t=1}= \frac{1}{2} \bigl(\phi_{p}\bigl(D^{3.5}z(t)\bigr) \bigr)'',\qquad \bigl(\phi_{p} \bigl(D^{3.5}z(t)\bigr)\bigr)''|_{t=0}=0. \end{aligned} $$

(37)

We apply Theorem 13. In (37), we have $\theta=\gamma=3.5$, $\alpha=0.5$, $\xi=\gamma=\frac{1}{3}$, $a(t)=t$, $f(z(t))=z(t)$ it is clear that (37) satisfies conditions (J₁), (J₄). Also considering $\beta=\frac {1}{2}$, (J₅) is satisfied. Thus by Theorem 13, the fractional differential equation (37) has a unique solution.

References

Hilfer, R: Applications of Fractional Calculus in Physics. World Scientific, Singapore (2000)
Book MATH Google Scholar
Kilbas, AA, Srivastava, HM, Trujillo, JJ: Theory and Applications of Fractional Differential Equations. North-Holland Mathematics Studies. Elsevier, Amsterdam (2006)
MATH Google Scholar
Miller, KS, Ross, B: An Introduction to the Fractional Calculus and Fractional Differential Equations. Wiley, New York (1993)
MATH Google Scholar
Oldhalm, KB, Spainer, J: The Fractional Calculus. Academic Press, New York (1974)
Google Scholar
Podlubny, I: Fractional Differential Equations. Academic Press, New York (1999)
MATH Google Scholar
Sabatier, J, Agrawal, OP, Machado, JAT: Advances in Fractional Calculus. Springer, Berlin (2007)
Book MATH Google Scholar
Lv, ZW: Existence results for m-point boundary value problems of nonlinear fractional differential equations with p-Laplacian operator. Adv. Differ. Equ. 2014, 69 (2014)
Article Google Scholar
Prasad, KR, Krushna, BMB: Existence of multiple positive solutions for p-Laplacian fractional order boundary value problems. Int. J. Anal. Appl. 6(1), 63-81 (2014)
Google Scholar
Yuan, Q, Yang, W: Positive solution for q-fractional four-point boundary value problems with p-Laplacian operator. J. Inequal. Appl. 2014, 481 (2014)
Article Google Scholar
Zhang, JJ, Liu, WB, Ni, JB, Chen, TY: Multiple periodic solutions of p-Laplacian equation with one side Nagumo condition. J. Korean Math. Soc. 45(6), 1549-1559 (2008)
Article MATH MathSciNet Google Scholar
Xu, X, Xu, B: Sign-changing solutions of p-Laplacian equation with a sub-linear nonlinearity at infinity. Electron. J. Differ. Equ. 2013, 61 (2013)
Article Google Scholar
Wang, B: Positive solutions for boundary value problems on a half line. Int. J. Math. Anal. 3(5), 221-229 (2009)
MATH MathSciNet Google Scholar
Herzallah, MAE, Baleanu, D: On fractional order hybrid differential equations. Abstr. Appl. Anal. 2014, Article ID 389386 (2014)
Article MathSciNet Google Scholar
Guo, D, Lakshmikantham, V: Nonlinear Problems in Abstract Cones. Academic Press, Orland (1988)
MATH Google Scholar
Han, Z, Lu, H, Sun, S, Yang, D: Positive solution to boundary value problem of p-Laplacian fractional differential equations with a parameter in the boundary. Electron. J. Differ. Equ. 2012, 213 (2012)
Article MathSciNet Google Scholar

Download references

Acknowledgements

We are thankful to the referees and editor for their valuable comments and remarks.

Author information

Authors and Affiliations

Department of Mathematical Sciences, University of South Africa, UNISA, P.O. Box 392, Pretoria, 0003, South Africa
Hossein Jafari
Department of Mathematical Sciences, University of Mazandaran, Babolsar, 47416-95447, Iran
Hossein Jafari
Department of Mathematics Computer Science, Cankaya University, Ankara, 06530, Turkey
Dumitru Baleanu
Institute of Space Sciences, MG-23, Magurele-Bucharest, 76900, Romania
Dumitru Baleanu
Department of Mathematics, University of Malakand, Dir Lower, P.O. Box 18000, Chakdara, Khybarpukhtunkhwa, Pakistan
Hasib Khan, Rahmat Ali Khan & Aziz Khan
Shaheed Benazir Bhutto University, Dir Upper, P.O. Box 18000, Sheringal, Khybarpakhtunkhwa, Pakistan
Hasib Khan

Authors

Hossein Jafari
View author publications
You can also search for this author in PubMed Google Scholar
Dumitru Baleanu
View author publications
You can also search for this author in PubMed Google Scholar
Hasib Khan
View author publications
You can also search for this author in PubMed Google Scholar
Rahmat Ali Khan
View author publications
You can also search for this author in PubMed Google Scholar
Aziz Khan
View author publications
You can also search for this author in PubMed Google Scholar

Corresponding author

Correspondence to Hossein Jafari.

Additional information

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

All authors contributed equally to the writing of this paper. All the authors read and approved the final manuscript.

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Reprints and permissions

About this article

Cite this article

Jafari, H., Baleanu, D., Khan, H. et al. Existence criterion for the solutions of fractional order p-Laplacian boundary value problems. Bound Value Probl 2015, 164 (2015). https://doi.org/10.1186/s13661-015-0425-2

Download citation

Received: 19 November 2014
Accepted: 25 August 2015
Published: 17 September 2015
DOI: https://doi.org/10.1186/s13661-015-0425-2

Existence criterion for the solutions of fractional order p-Laplacian boundary value problems

Abstract

1 Introduction

Definition 1

Definition 2

Lemma 3

Lemma 4

Definition 5

Definition 6

Lemma 7

2 Main results

Lemma 8

Proof

Lemma 9

Lemma 10

2.1 Existence and uniqueness of solutions

Theorem 11

Proof

Theorem 12

Proof

Theorem 13

Proof

3 Examples

Example 1

Example 2

Example 3

References

Acknowledgements

Author information

Authors and Affiliations

Corresponding author

Additional information

Competing interests

Authors’ contributions

Rights and permissions

About this article

Cite this article

Share this article

Keywords