Nonlocal Hadamard fractional integral conditions for nonlinear Riemann-Liouville fractional differential equations

In this paper, we introduce a new class of boundary value problems consisting of a fractional differential equation of Riemann-Liouville type, $D_q^{RL}x(t)=f(t,x(t))$, $t\in [0,T]$, subject to the Hadamard fractional integral conditions $x(0)=0$, $x(T)={\sum }_{i=1}^n\alpha _i^H{I}^{p_i}x({\eta }_i)$. Existence and uniqueness results are obtained by using a variety of fixed point theorems. Examples illustrating the results obtained are also presented.

MSC: 34A08, 34B15.

In this paper, we concentrate on the study of existence and uniqueness of solutions for the nonlinear Riemann-Liouville fractional differential equation with nonlocal Hadamard fractional integral boundary conditions of the form

where $1<q\le 2$, $D_q^{RL}$ is the standard Riemann-Liouville fractional derivative of order q, $I_{p_i}^H$ is the Hadamard fractional integral of order $p_i>0$, ${\eta }_i\in (0,T)$, $f:[0,T]\times \mathbb{R}\to \mathbb{R}$, and ${\alpha }_i\in \mathbb{R}$, $i=1,2,\dots ,n$ are real constants such that ${\sum }_{i=1}^n\frac{{\alpha }_i{\eta }_i^{q-1}}{{(q-1)}^{p_i}}\ne T^{q-1}$.

Several interesting and important results concerning existence and uniqueness of solutions, stability properties of solutions, analytic and numerical methods of solutions for fractional differential equations can be found in the recent literature on the topic and the search for more and more results is in progress. Fractional-order operators are nonlocal in nature and take care of the hereditary properties of many phenomena and processes. Fractional calculus has also emerged as a powerful modeling tool for many real world problems. For examples and recent development of the topic, see [1]–[14]. However, it has been observed that most of the work on the topic involves either Riemann-Liouville or Caputo type fractional derivatives. Besides these derivatives, the Hadamard fractional derivative is another kind of fractional derivative that was introduced by Hadamard in 1892 [15]. This fractional derivative differs from the other ones in the sense that the kernel of the integral (in the definition of the Hadamard derivative) contains a logarithmic function of an arbitrary exponent. For background material of the Hadamard fractional derivative and integral, we refer to [2], [16]–[22].

In the present paper we initiate the study of boundary value problems like (1.1)-(1.2), in which we combine Riemann-Liouville fractional differential equations subject to the Hadamard fractional integral boundary conditions. The key tool for this combination is Property 2.25 from [2], p.113. To the best of the authors’ knowledge this is the first paper dealing with the Riemann-Liouville fractional differential equation subject to Hadamard type integral boundary conditions.

Several new existence and uniqueness results are obtained by using a variety of fixed point theorems. Thus, in Theorem 3.1 we present an existence and uniqueness result via Banach’s fixed point theorem, while in Theorems 3.2 and 3.3 we give two other existence and uniqueness results via Banach’s fixed point theorem and Hölder inequality and nonlinear contractions, respectively. In the sequel existence results are obtained in Theorem 3.4, via Krasnoselskii’s fixed point theorem, in Theorem 3.5 via Leray-Schauder’s nonlinear alternative and finally in Theorem 3.7 via Leray-Schauder’s degree theory. Examples illustrating the results obtained are also presented.

In this section, we introduce some notations and definitions of fractional calculus and present preliminary results needed in our proofs later.

Definition 2.1

The Riemann-Liouville fractional derivative of order $q>0$ of a continuous function $f:(0,\mathrm{\infty })\to \mathbb{R}$ is defined by

where $n=[q]+1$, $[q]$ denotes the integer part of a real number q. Here Γ is the Gamma function defined by $\mathrm{\Gamma }(q)={\int }_0^{\mathrm{\infty }}{e}^{-s}{s}^{q-1}ds$.

Definition 2.2

The Riemann-Liouville fractional integral of order $q>0$ of a continuous function $f:(0,\mathrm{\infty })\to \mathbb{R}$ is defined by

Definition 2.3

The Hadamard derivative of fractional order q for a function $f:(0,\mathrm{\infty })\to \mathbb{R}$ is defined as

where $log(\cdot )={log}_e(\cdot )$, provided the integral exists.

Definition 2.4

The Hadamard fractional integral of order $q\in {\mathbb{R}}^{+}$ of a function $f(t)$, for all $t>0$, is defined as

provided the integral exists.

Lemma 2.1

([2], p.113])

Let$q>0$and$n>0$. Then the following formulas:

hold.

Lemma 2.2

Let$q>0$and$x\in C(0,T)\cap L(0,T)$. Then the fractional differential equation

has a unique solution

where$c_i\in \mathbb{R}$, $i=1,2,\dots ,n$, and$n-1<q<n$.

Lemma 2.3

Let$q>0$. Then for$x\in C(0,T)\cap L(0,T)$we have

where$c_i\in \mathbb{R}$, $i=1,2,\dots ,n$, and$n-1<q<n$.

Lemma 2.4

Let${\sum }_{i=1}^n(({\alpha }_i{\eta }_i^{q-1})/({(q-1)}^{p_i}))\ne T^{q-1}$, $1<q\le 2$, $p_i>0$, ${\alpha }_i\in \mathbb{R}$, ${\eta }_i\in (0,T)$, $i=1,2,3,\dots ,n$, and$h\in C([0,T],\mathbb{R})$. Then the nonlocal Hadamard fractional integral problem for the nonlinear Riemann-Liouville fractional differential equation

subject to the boundary conditions

has a unique solution given by

where

Proof

Using Lemmas 2.2-2.3, (2.1) can be expressed as an equivalent integral equation

for $c_1,c_2\in \mathbb{R}$. The first condition of (2.2) implies that $c_2=0$. Taking the Hadamard fractional integral of order $p_i>0$ for (2.5) and using the property of the Hadamard fractional integral $({}_H{I}^{p_i}{s}^{q-1})(t)={(q-1)}^{-p_i}{t}^{q-1}$, we get

The second condition of (2.2) implies that

Thus,

Substituting the values of $c_1$ and $c_2$ in (2.5), we obtain the solution (2.3). □

Throughout this paper, for convenience, we use the following expressions:

for $t\in [0,T]$ and

where ${\eta }_i\in (0,T)$ for $i=1,2,\dots ,n$.

Let $\mathcal{C}=C([0,T],\mathbb{R})$ denote the Banach space of all continuous functions from $[0,T]$ to ℝ endowed with the norm defined by $\parallel x\parallel ={sup}_{t\in [0,T]}|x(t)|$. As in Lemma 2.4, we define an operator $\mathcal{A}:\mathcal{C}\to \mathcal{C}$ by

It should be noticed that problem (1.1)-(1.2) has a solution if and only if the operator $\mathcal{A}$ has fixed points.

In the following, for the sake of convenience, we set a constant

In the following subsections we prove existence, as well as existence and uniqueness results, for the boundary value problem (1.1)-(1.2) by using a variety of fixed point theorems.

3.1 Existence and uniqueness result via Banach’s fixed point theorem

Theorem 3.1

Assume that:

(H₁):there exists a constant$L>0$such that$|f(t,x)-f(t,y)|\le L|x-y|$, for each$t\in [0,T]$and$x,y\in \mathbb{R}$.

If

where Ω is defined by (3.2), then the boundary value problem (1.1)-(1.2) has a unique solution on$[0,T]$.

Proof

We transform the BVP (1.1)-(1.2) into a fixed point problem, $x=\mathcal{A}x$, where the operator $\mathcal{A}$ is defined as in (3.1). Observe that the fixed points of the operator $\mathcal{A}$ are solutions of problem (1.1)-(1.2). Applying the Banach contraction mapping principle, we shall show that $\mathcal{A}$ has a unique fixed point.

We let ${sup}_{t\in [0,T]}|f(t,0)|=M<\mathrm{\infty }$, and choose

Now, we show that $\mathcal{A}{B}_r\subset B_r$, where $B_r=\{x\in \mathcal{C}:\parallel x\parallel \le r\}$. For any $x\in B_r$, we have

which implies that $\mathcal{A}{B}_r\subset B_r$.

Next, we let $x,y\in \mathcal{C}$. Then for $t\in [0,T]$, we have

which implies that $\parallel \mathcal{A}x-\mathcal{A}y\parallel \le L\mathrm{\Omega }\parallel x-y\parallel$. As $L\mathrm{\Omega }<1$, $\mathcal{A}$ is a contraction. Therefore, we deduce, by the Banach contraction mapping principle, that $\mathcal{A}$ has a fixed point which is the unique solution of the boundary value problem (1.1)-(1.2). The proof is completed. □

3.2 Existence and uniqueness result via Banach’s fixed point theorem and Hölder inequality

Theorem 3.2

Suppose that: $f:[0,T]\times \mathbb{R}\to \mathbb{R}$is a continuous function satisfying the following assumption:

(H₂):$|f(t,x)-f(t,y)|\le \delta (t)|x-y|$, for$t\in [0,T]$, $x,y\in \mathbb{R}$and$\delta \in L^{\frac{1}{\sigma }}([0,T],{\mathbb{R}}^{+})$, $\sigma \in (0,1)$.

Denote$\parallel \delta \parallel ={({\int }_0^T{|\delta (s)|}^{\frac{1}{\sigma }}ds)}^{\sigma }$. If

then the boundary value problem (1.1)-(1.2) has a unique solution.

Proof

For $x,y\in C([0,T],\mathbb{R})$ and for each $t\in [0,T]$, by Hölder’s inequality, we have

It follows that $\mathcal{A}$ is contraction mapping. Hence Banach’s fixed point theorem implies that $\mathcal{A}$ has a unique fixed point, which is the unique solution of the boundary value problem (1.1)-(1.2). The proof is completed. □

3.3 Existence and uniqueness result via nonlinear contractions

Definition 3.1

Let E be a Banach space and let $\mathcal{A}:E\to E$ be a mapping. $\mathcal{A}$ is said to be a nonlinear contraction if there exists a continuous nondecreasing function $\mathrm{\Psi }:{\mathbb{R}}^{+}\to {\mathbb{R}}^{+}$ such that $\mathrm{\Psi }(0)=0$ and $\mathrm{\Psi }(\epsilon )<\epsilon$ for all $\epsilon >0$ with the property:

Lemma 3.1

(Boyd and Wong) [23]

Let E be a Banach space and let$\mathcal{A}:E\to E$be a nonlinear contraction. Then$\mathcal{A}$has a unique fixed point in E.

Theorem 3.3

Let$f:[0,T]\times \mathbb{R}\to \mathbb{R}$be a continuous function satisfying the assumption:

(H₃):$|f(t,x)-f(t,y)|\le h(t)\frac{|x-y|}{H^{\ast }+|x-y|}$, for$t\in [0,T]$, $x,y\ge 0$, where$h:[0,T]\to {\mathbb{R}}^{+}$is continuous and$H^{\ast }$the constant defined by

Then the boundary value problem (1.1)-(1.2) has a unique solution.

Proof

We define the operator $\mathcal{A}:\mathcal{C}\to \mathcal{C}$ as in (3.1) and the continuous nondecreasing function $\mathrm{\Psi }:{\mathbb{R}}^{+}\to {\mathbb{R}}^{+}$ by

Note that the function Ψ satisfies $\mathrm{\Psi }(0)=0$ and $\mathrm{\Psi }(\epsilon )<\epsilon$ for all $\epsilon >0$.

For any $x,y\in \mathcal{C}$ and for each $t\in [0,T]$, we have

This implies that $\parallel \mathcal{A}x-\mathcal{A}y\parallel \le \mathrm{\Psi }(\parallel x-y\parallel )$. Therefore $\mathcal{A}$ is a nonlinear contraction. Hence, by Lemma 3.1 the operator $\mathcal{A}$ has a unique fixed point which is the unique solution of the boundary value problem (1.1)-(1.2). This completes the proof. □

3.4 Existence result via Krasnoselskii’s fixed point theorem

Lemma 3.2

(Krasnoselskii’s fixed point theorem) [24]

Let M be a closed, bounded, convex, and nonempty subset of a Banach space X. Let A, B be the operators such that (a) $Ax+Bx\in M$whenever$x,y\in M$; (b) A is compact and continuous; (c) B is a contraction mapping. Then there exists$z\in M$such that$z=Az+Bz$.

Theorem 3.4

Let$f:[0,T]\times \mathbb{R}\to \mathbb{R}$be a continuous function satisfying (H₁). In addition we assume that:

(H₄):$|f(t,x)|\le \phi (t)$, $\mathrm{\forall }(t,x)\in [0,T]\times \mathbb{R}$, and$\phi \in C([0,T],{\mathbb{R}}^{+})$.

Then the boundary value problem (1.1)-(1.2) has at least one solution on$[0,T]$provided

Proof

Setting ${sup}_{t\in [0,T]}\phi (t)=\parallel \phi \parallel$ and choosing

(where Ω is defined by (3.2)), we consider $B_{\rho }=\{x\in \mathcal{C}([0,T],\mathbb{R}):\parallel x\parallel \le \rho \}$. We define the operators ${\mathcal{A}}_1$ and ${\mathcal{A}}_2$ on $B_{\rho }$ by

For any $x,y\in B_{\rho }$, we have

This shows that ${\mathcal{A}}_{1}x+{\mathcal{A}}_{2}y\in B_{\rho }$. It is easy to see using (3.5) that ${\mathcal{A}}_2$ is a contraction mapping.

Continuity of f implies that the operator ${\mathcal{A}}_1$ is continuous. Also, ${\mathcal{A}}_1$ is uniformly bounded on $B_{\rho }$ as

Now we prove the compactness of the operator ${\mathcal{A}}_1$.

We define ${sup}_{(t,x)\in [0,T]\times B_{\rho }}|f(t,x)|=\overline{f}<\mathrm{\infty }$, and consequently we have

which is independent of x and tend to zero as $t_2-t_1\to 0$. Thus, ${\mathcal{A}}_1$ is equicontinuous. So ${\mathcal{A}}_1$ is relatively compact on $B_{\rho }$. Hence, by Arzelá-Ascoli’s theorem, ${\mathcal{A}}_1$ is compact on $B_{\rho }$. Thus all the assumptions of Lemma 3.2 are satisfied. So the conclusion of Lemma 3.2 implies that the boundary value problem (1.1)-(1.2) has at least one solution on $[0,T]$. □

3.5 Existence result via Leray-Schauder’s nonlinear alternative

Theorem 3.5

(Nonlinear alternative for single valued maps) [25]

Let E be a Banach space, C a closed, convex subset of E, U an open subset of C and$0\in U$. Suppose that$\mathcal{A}:\overline{U}\to C$is a continuous, compact (that is, $\mathcal{A}(\overline{U})$is a relatively compact subset of C) map. Then:

1. (i)

   either $\mathcal{A}$ has a fixed point in $\overline{U}$, or

2. (ii)

   there is a $x\in \partial U$ (the boundary of U in C) and $\lambda \in (0,1)$ with $x=\lambda \mathcal{A}(x)$.

Theorem 3.6

Assume that:

(H₅):there exist a continuous nondecreasing function$\psi :[0,\mathrm{\infty })\to (0,\mathrm{\infty })$and a function$p\in C([0,T],{\mathbb{R}}^{+})$such that

(H₆):there exists a constant$M>0$such that

where Ω is defined by (3.2).

Then the boundary value problem (1.1)-(1.2) has at least one solution on$[0,T]$.

Proof

Let the operator $\mathcal{A}$ be defined by (3.1). Firstly, we shall show that $\mathcal{A}$maps bounded sets (balls) into bounded sets in$C([0,T],\mathbb{R})$. For a number $r>0$, let $B_r=\{x\in C([0,T],\mathbb{R}):\parallel x\parallel \le r\}$ be a bounded ball in $C([0,T],\mathbb{R})$. Then for $t\in [0,T]$ we have

and consequently,

Next we will show that $\mathcal{A}$maps bounded sets into equicontinuous sets of$C([0,T],\mathbb{R})$. Let ${\tau }_1,{\tau }_2\in [0,T]$ with ${\tau }_1<{\tau }_2$ and $x\in B_r$. Then we have

As ${\tau }_2-{\tau }_1\to 0$, the right-hand side of the above inequality tends to zero independently of $x\in B_r$. Therefore by Arzelá-Ascoli’s theorem the operator $\mathcal{A}:C([0,T],\mathbb{R})\to C([0,T],\mathbb{R})$ is completely continuous.

Let x be a solution. Then, for $t\in [0,T]$, and following similar computations to the first step, we have

which leads to

In view of (H₆), there exists M such that $\parallel x\parallel \ne M$. Let us set

We see that the operator $\mathcal{A}:\overline{U}\to C([0,T],\mathbb{R})$ is continuous and completely continuous. From the choice of U, there is no $x\in \partial U$ such that $x=\nu \mathcal{A}x$ for some $\nu \in (0,1)$. Consequently, by the nonlinear alternative of Leray-Schauder type, we deduce that $\mathcal{A}$ has a fixed point $x\in \overline{U}$ which is a solution of the boundary value problem (1.1)-(1.2). This completes the proof. □

3.6 Existence result via Leray-Schauder’s degree theory

Theorem 3.7

Let$f:[0,T]\times \mathbb{R}\to \mathbb{R}$be a continuous function. Suppose that

(H₅):there exist constants$0\le \kappa <{\mathrm{\Omega }}^{-1}$and$M>0$such that

where Ω is defined by (3.2).

Then the boundary value problem (1.1)-(1.2) has at least one solution on$[0,T]$.

Proof

We define an operator $\mathcal{A}:\mathcal{C}\to \mathcal{C}$ as in (3.1). In view of the fixed point problem

We shall prove the existence of at least one solution $x\in C[0,T]$ satisfying (3.7). Set a ball $B_R\subset C[0,T]$, as

where a constant radius $R>0$. Hence, we shall show that $\mathcal{A}:{\overline{B}}_R\to C[0,T]$ satisfies the condition

We set

As shown in Theorem 3.6 we see that the operator $\mathcal{A}$ is continuous, uniformly bounded, and equicontinuous. Then, by Arzelá-Ascoli’s theorem, a continuous map $h_{\theta }$ defined by $h_{\theta }(x)=x-H(\theta ,x)=x-\theta \mathcal{A}x$ is completely continuous. If (3.8) holds, then the following Leray-Schauder degrees are well defined, and by the homotopy invariance of topological degree it follows that

where I denotes the unit operator. By the nonzero property of the Leray-Schauder degree, $h_1(x)=x-\mathcal{A}x=0$ for at least one $x\in B_R$. Let us assume that $x=\theta \mathcal{A}x$ for some $\theta \in [0,1]$ and for all $t\in [0,T]$ so that