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On Hyers–Ulam stability of a multi-order boundary value problems via Riemann–Liouville derivatives and integrals
Advances in Difference Equations volume 2020, Article number: 547 (2020)
Abstract
In this research paper, we introduce a general structure of a fractional boundary value problem in which a 2-term fractional differential equation has a fractional bi-order setting of Riemann–Liouville type. Moreover, we consider the boundary conditions of the proposed problem as mixed Riemann–Liouville integro-derivative conditions with four different orders which cover many special cases studied before. In the first step, we investigate the existence and uniqueness of solutions for the given multi-order boundary value problem, and then the Hyers–Ulam stability is another notion in this regard which we study. Finally, we provide two illustrative examples to support our theoretical findings.
1 Introduction and preliminaries
Fractional differential problems have drawn much interest in recent years owing to their extensive utilization in different branches of science such as engineering, mechanics, potential theory, biology, chemistry, etc. (see [1–11]). Many researchers helped in developments on the existence and uniqueness results of fractional differential equations [12–26]. Stability is a notion in physics, and most phenomena include the concept. In fact, stability of physical phenomena has an old history, and one can find a lot of works in the literature not only in the last century but also before it [27–36]. During recent decades, considerable attention has been given to the study of the Hyers–Ulam stability of functional differential and integral equations [37–54].
In 2016, Niyom et al. studied the boundary value problem via four-order fractional Riemann–Liouville derivatives
under some conditions [55]. In 2017, Ntouyas et al. reviewed a boundary value problem via multiple orders of fractional derivatives and integrals
under some conditions [15]. In 2018, Xu et al. investigated the existence of solutions and Hyers–Ulam stability for the fractional differential equations
under some conditions [39]. They considered two-term class of three-point boundary value problems with Riemann–Liouville fractional derivatives and integrals [39].
Now, by using and mixing the idea of the above-mentioned works, we consider a new category of boundary value problem including multi-order Riemann–Liouville fractional equation supplemented with different linear integro-derivative boundary conditions as follows:
where \(2<{\theta }<{k}\), \(0<{\lambda }\), \({\mu _{1}},{\mu _{2}} \leq 1\), \(0\leq {\gamma _{1}}\), \({\gamma _{2}}<{k}-{ \theta }\), \({q_{1}}, {q_{2}} \in \mathbb{R}^{+} \), \(\mathcal{D}^{{\beta }}\) is the Riemann–Liouville fractional derivative of order \({\beta }\in \{{k},{\theta }, { \gamma _{1}}, {\gamma _{2}}\} \), \(\mathcal{I}^{ {\eta } } \) denotes the Riemann–Liouville fractional integral of order \({\eta } \in \{ {q_{1}}, {q_{2}}\}\), and the map \(\hat{\Upsilon }: [0,T]\times \mathbb{R} \to \mathbb{R}\) is continuous.
As many researchers would like to investigate the stability notion of different boundary value problems, this can be a motivation for us to study the stability of complicated systems supplemented with general boundary conditions. Hence more precisely, our main goal in the present manuscript is to obtain some existence criteria of the solutions for a new general boundary value problem including 2-term fractional differential equation (4) which contains multi-order Riemann–Liouville fractional derivatives and integrals. To fulfil this aim, we use the well-known standard fixed point theorems. Also, in the sequel, we investigate the Hyers–Ulam stability of the proposed problem (4) in the special case \({\mu _{1}}=1\) and \({\mu _{2}}=1\). Finally, we present two illustrative examples to show the validity of our theoretical findings. We believe that such proposed boundary value problem is general, and it involves many fractional dynamical systems as special cases in physics and other applied sciences.
2 Preliminaries
Now, let us provide some basic notions. It is known that the Riemann–Liouville fractional integral of order η of a real-valued function \(g:(0,\infty )\to \mathbb{R}\) is defined by \(\mathcal{I}^{{\eta }}g(t) =\int _{0}^{t} \frac{(t-s)^{{\eta }-1}}{\Gamma ({\eta })}g(s)\,ds\), provided the right-hand side is point-wise defined on \((0,\infty ) \), where Γ is the gamma function [1]. The Riemann–Liouville fractional derivative of order k of a function \(g:(0,\infty )\to \mathbb{R}\) is defined by \(\mathcal{D}^{{\beta }}g(t) = \frac{1}{\Gamma (n-{\beta })} (\frac{d}{dt} )^{n} \int _{0}^{t}\frac{g(s)}{(t-s)^{{\beta }-n+1}}\,ds\), where \(n=[{\beta }]+1\), \([{\beta }] \) denotes the integer part of real number β provided the right-hand side is point-wise defined on \((0,\infty ) \) [1]. We need the next results.
Lemma 1
Let \({k}>0 \)and \(u\in C(0,1)\), where \(C(0,1)\)stands for the space of all continuous real-valued functions defined on \((0,1)\). Then the fractional differential equation \(\mathcal{D}^{{k}} u(t)=0 \)has a general solution \(u(t)=C_{1} t^{{k}-1}+C_{1} t^{{k}-2}+\cdots+C_{1} t^{{k}-n}\), where \(n-1\leq {k} < n \)and \(C_{1},\ldots , C_{n}\)are some real constants.
Lemma 2
([1])
Let \({k}>0\)and \(u\in C(0,1)\). Then we have
where \(n-1\leq {k} < n \)and \(C_{1},\ldots , C_{n}\)are some real constants.
Theorem 3
(Krasnoselskii’s fixed point theorem, [56])
Let \(\mathcal{M} \)be a closed, bounded, convex, and nonempty subset of a Banach space \(\mathcal{X}\). Assume that \(\mathcal{A}_{1}\)and \(\mathcal{A}_{2} \)are two operators on \(\mathcal{M}\)such that
-
(a)
\(\mathcal{A}_{1}u + \mathcal{A}_{2}w \in \mathcal{M}\)for all \(u, w \in \mathcal{M} \),
-
(b)
\(\mathcal{A}_{1}\)is compact and continuous,
-
(c)
\(\mathcal{A}_{2} \)is a contraction.
Then there exists \(z \in \mathcal{M} \)such that \(z = \mathcal{A}_{1}z + \mathcal{A}_{2}z \).
Theorem 4
(Leray–Schauder’s nonlinear alternative, [57])
Let \(\mathcal{X} \)be a Banach space, \({\mathcal{B}} \)be a closed, convex subset of \(\mathcal{X} \), \(\mathcal{U}\)be an open subset of \(\mathcal{B}\), and \(0\in \mathcal{U}\). Assume that \(\mathcal{P} : \bar{\mathcal{U}} \to \mathcal{B} \)is a continuous and compact map. Then either
-
(a)
\(\mathcal{P} \)has a fixed point in \(\bar{\mathcal{U}} \), or
-
(b)
there is \(u \in \partial \mathcal{U} \) (the boundary of \(\mathcal{U} \)) and \({\tau } \in (0,1) \)with \(u = {\tau } \mathcal{P}(u) \).
Lemma 5
([39])
Let \(\alpha >0\), \(a>0 \), \(g(t,s) \)be a nonnegative continuous bounded function defined on \([0,T]\times [0,T] \)and nondecreasing with respect to the first variable and nonincreasing with respect to the second variable. Assume that \(u(t) \)is nonnegative and integrable on \([0,T] \)with \(u(t)\leq a+\int _{0}^{t}g(t,s)(t-s)^{\alpha -1}u(s)\,ds\)for \(t\in [0,T]\). Then we have
Theorem 6
(Banach contraction principle, [57])
Let \(\mathcal{X}\)be a Banach space and \(\mathcal{P}: \mathcal{X}\to \mathcal{X}\)be a contraction. Then \(\mathcal{P}\)has a unique fixed point.
3 Some existence results
Let \(T >0 \), \(J=[0,T] \), and \(\mathcal{C}= C(J,\mathbb{R}) \) be the Banach space of continuous mappings with the sup norm \(\Vert u\Vert =\sup_{t\in J}\vert u(t)\vert \). We first provide our key result.
Lemma 7
A map \(u_{0}\)is a solution for boundary value problem (4) if and only if \(u_{0}\)is a solution for the integral equation
where
Proof
First, assume that \(u_{0}\) is a solution for problem (4). Then we have
By taking the Riemann–Liouville fractional integral of order k from both sides of equation (7), we obtain
for some real constants \(C_{1}\), \(C_{2}\), and \(C_{3}\). For \(2<{k}<3 \), the first boundary condition of (4) implies that \(C_{3}=0 \). Hence,
By using the Riemann–Liouville fractional derivative and integral of order α and β respectively with \({\alpha }\in \{{\gamma _{1}}, {\gamma _{2}}\}\), \({\beta } \in \{{q_{1}}, {q_{1}}\} \), \(0<\alpha <{k}-{\theta } \), and \(2<{\theta }<{k}\), we get
and
By replacing the values \({\alpha }={\gamma _{1}}\), \({\alpha }={\gamma _{2}}\), \({\beta }={q_{1}} \), and \({\beta }={q_{2}} \) and using the second condition of (4), we get
and
which leads to
and
By inserting the values of constants \(C_{1}\) and \(C_{2} \) in (8), we find that \(u_{0}\) satisfies (5). Some calculations show that the converse part holds. This completes the proof. □
Based on Lemma 7, define the operator \(\mathcal{F}:\mathcal{C} \to \mathcal{C} \) by
Note that boundary value problem (4) has solution \(u_{0}\) if and only if \(u_{0}\) is a fixed point of the operator \(\mathcal{F}u\). To simplify calculations, we use the notations
and
Theorem 8
Suppose that \(\hat{\Upsilon }:J\times \mathbb{R}\to \mathbb{R} \)is a continuous map and there exists a constant \(\mathcal{L} > 0 \)such that \(|\hat{\Upsilon }(t, u)-\hat{\Upsilon }(t, u')|\leq \mathcal{L}|u-u'| \)for all \(t\in J \)and \(u, u'\in \mathbb{R}\). If \(\mathcal{L}\mathcal{W}_{2}+\mathcal{W}_{1}<1\), then problem (4) has a unique solution, where \(\mathcal{W}_{1} \)and \(\mathcal{W}_{2} \)are defined by (10) and (11).
Proof
Put \(\sup_{t\in J}|\hat{\Upsilon } (t, 0)|= {\mathcal{N}} < \infty \) and choose
where \(\Lambda _{i} \)\(i\in \{1, 2, 3, 4\} \) are defined by (7). Set \(\mathcal{B}_{{\mathcal{R}}}= \{u \in \mathcal{C}: \|u\| \leq {\mathcal{R}}\} \). We show that \(\mathcal{F}\mathcal{B}_{{\mathcal{R}}}\subset \mathcal{B}_{{\mathcal{R}}} \). For each \(u\in \mathcal{B}_{{\mathcal{R}}}\), we have
Thus, \(\Vert Fu\Vert \leq {\mathcal{R}} \) and so \(\mathcal{F}\mathcal{B}_{{\mathcal{R}}}\subset \mathcal{B}_{{\mathcal{R}}} \). Let \(u, u'\in \mathcal{C} \). For each \(t\in J \), we have
Hence, \(\|\mathcal{F}u-\mathcal{F}u'\| \leq (\mathcal{L}\mathcal{W}_{2}+ \mathcal{W}_{1}) \|u-u'\|\) and so \(\mathcal{F} \) is a contraction. By using the principle of contraction, \(\mathcal{F} \) has a unique fixed point which is the unique solution for problem (4). □
Here, by using Krasnoselskii’s fixed point theorem, we provide our next existence result.
Theorem 9
Suppose that \(\hat{\Upsilon }:J\times \mathbb{R}\to \mathbb{R} \)is a continuous map and there exists a constant \(\mathcal{L} > 0 \)such that \(|\hat{\Upsilon }(t, u)-\hat{\Upsilon }(t, u')|\leq \mathcal{L}|u-u'| \)for each \(t\in J \)and \(u, u'\in \mathbb{R}\). If there is \(\mathcal{V}(t)\in C(J,\mathbb{R}^{+})\)such that \(\hat{\Upsilon } (t,u)\leq \mathcal{V}(t)\)for all \((t,u)\in J\times \mathbb{R} \)and \(\mathcal{W}_{1}<1 \), then problem (4) has at least one solution. Here, \(\mathcal{W}_{1}\)is given by (10).
Proof
Let \(\Vert \mathcal{V} \Vert =\sup_{t\in J}|\mathcal{V}(t)| \). Consider the set \({\mathcal{B}_{r}}= \{u\in \mathcal{C} : \|u\|\leq { r}\} \), where
and \(\Lambda _{1}\), \(\Lambda _{2}\), \(\Lambda _{3}\), \(\Lambda _{4}\), and \(\mathcal{W}_{1}\) are given by (7) and (10), respectively. For each \(t \in J \), define the operators \(\mathcal{F}_{1} \) and \(\mathcal{F}_{2} \) on \({\mathcal{B}_{r}} \) by
and
We show that \(\mathcal{F}_{2}u +\mathcal{F}_{2}u' \in {\mathcal{B}_{r}} \). Let \(u, u' \in {\mathcal{B}_{r}} \). Then we have
and so \(\mathcal{F}_{1}u +\mathcal{F}_{2}u' \in {\mathcal{B}_{r}} \). Now, we prove \(\mathcal{F}_{1} \) is a contraction. For every u, \(u'\in {\mathcal{B}_{r}} \), we have
Since \(\mathcal{W}_{1}< 1 \), \(\mathcal{F}_{1} \) is a contraction. Utilizing the continuity of the function ϒ̂, we find that the operator \(\mathcal{F}_{2} \) is continuous. If \(u\in {\mathcal{B}_{r}}\), then
This means that the operator \(\mathcal{F}_{2} \) is uniformly bounded on \({\mathcal{B}_{r}}\). Now, we show that \(\mathcal{F}_{2} \) is equicontinuous. Set \(\sup_{t\in J,u\in \mathcal{B}_{r}}|\hat{\Upsilon }(t,u)|= \overline{ {\mathcal{M}}}\). For each \(t_{1} \), \(t_{2} \) with \(t_{2} > t_{1} \) and \(u \in {\mathcal{B}_{r}} \), we have
The right-hand side of the above inequality tends to zero independently of u as \(t_{2} \) tends to \(t_{1} \). Hence, \(\mathcal{F}_{2} \) is equicontinuous, and so \(\mathcal{F}_{2} \) is relatively compact on \({\mathcal{B}_{r}} \). Now, by using the Arzela–Ascoli theorem, \(\mathcal{F}_{2} \) is compact on \({\mathcal{B}_{r}} \). Now, by using Theorem 3, boundary value problem (4) has at least one solution. □
Here, by applying the Leray–Schauder theorem, we give another existence result.
Theorem 10
Suppose that \(\hat{\Upsilon }:J\times \mathbb{R} \to \mathbb{R} \)is a continuous map and there are nondecreasing continuous function \(\Psi :[0,\infty )\to (0,\infty ) \)and \(\Phi \in C(J,\mathbb{R}^{+})\)such that \(|\hat{\Upsilon }(t,u)|\leq \Phi (t)\Psi (\|u\|)\)for all \((t,u)\in J\times \mathbb{R}\). Assume that there exists a constant \({\mathcal{Q}} > 0 \)such that
where \(\mathcal{W}_{1}\), \(\mathcal{W}_{2}\)are defined by (10) and (11), respectively. Then boundary value problem (4) has at least one solution.
Proof
Consider the operator \(\mathcal{F} \) defined by (9). We show that \(\mathcal{F} \) maps bounded sets into bounded sets of \(\mathcal{C} \). Let \(\rho > 0 \) and \({\mathcal{B}_{\rho } }= \{u\in \mathcal{C}:\|u\|\leq { \rho }\} \) be a bounded ball in \(\mathcal{C} \) and \(t\in J \). Then we have
and consequently
Now, we prove that the operator \(\mathcal{F} \) maps bounded sets into equicontinuous sets of \(\mathcal{C} \). Assume that \(t_{1} \), \(t_{2} \in J \) with \(t_{1} < t_{2} \) and \(u \in {\mathcal{B}_{\rho }} \). Then we have
If \(t_{2}-t_{1}\to 0\), then the right-hand side of the above inequality tends to zero independently of \(x\in {\mathcal{B}_{\rho }} \). Thus, by using the Arzela–Ascoli theorem, the operator \(\mathcal{F}: \mathcal{C}\to \mathcal{C} \) is completely continuous. The desired result is deduced from the Leray–Schauder theorem 4 once we prove the boundedness of the set of the solutions for the equation \(u={\omega } \mathcal{F}u \) for some \({\omega } \in (0,1) \). Let u be a solution of the last equation. For each \(t\in J \), we have
and so \(\frac{\|u\|\vert {\Theta }\vert }{\|u\|\vert {\Theta }\vert \mathcal{W}_{1} +\Psi (\|u\|)\|\Phi \|\vert {\Theta }\vert \mathcal{W}_{2}+T^{{k}-1}(|{\Lambda _{2}}{\delta _{2}}| +|{\Lambda _{4}}{\delta _{1}}|)+ T^{{k}-2}(|{\Lambda _{1}}{\delta _{2}}|+|{\Lambda _{3}}{\delta _{1}}|)} <1\). Choose the constant \({\mathcal{Q}} \) with \(\Vert u\Vert \ne {\mathcal{Q}} \). Put \(\mathcal{U}=\{x\in C: \Vert x \Vert <{\mathcal{Q}}\}\). One can check that the operator \(\mathcal{F}:\bar{\mathcal{U}}\to \mathcal{C} \) is continuous and completely continuous. In view of the choice of \(\mathcal{U} \), there is no \(u\in \partial \mathcal{U} \) so that \(u={\omega } \mathcal{F}u\) for some \({\omega } \in (0,1) \). Now, by using the Leray–Schauder theorem, the operator \(\mathcal{F} \) has a fixed point \(u\in \bar{\mathcal{U}} \) which is a solution of boundary value problem (4). □
4 Stability analysis
In this section, we study the Hyers–Ulam stability of the boundary value problem
which is a special case of problem (4) when we take \({\mu _{1}=\mu _{2}}=1\).
Definition 11
Problem (12) is called Hyers–Ulam stable whenever there exists a real constant \({\ell }>0 \) such that, for each \(\varepsilon >0\) and \(u(t)\in C_{\mathbb{R}}([0,T])\) satisfying
there is a solution \(v(t)\in C_{\mathbb{R}}([0,T])\) of problem (12) such that \(\vert u(t)-v(t) \vert \leq {\ell }\varepsilon \) for all \(t\in [0,T]\).
Theorem 12
Suppose that \(\hat{\Upsilon }:J\times \mathbb{R}\to \mathbb{R} \)is a continuous map and there exists a constant \(\mathcal{L} > 0 \)such that \(|\hat{\Upsilon }(t, u)-\hat{\Upsilon }(t, u')|\leq \mathcal{L}|u-u'| \)for all \(t\in J \)and \(u, u'\in \mathbb{R}\). Then boundary value problem (12) is Hyers–Ulam stable.
Proof
Let \(\varepsilon >0 \) and \(u(t)\in C_{\mathbb{R}}([0,T])\) be such that
Choose a function g satisfying \({\lambda }\mathcal{D}^{{k}}u(t)+(1-{ \lambda })\mathcal{D}^{{\theta }}(u(t))= \hat{\Upsilon } (t,u(t) )+g(t)\) and \(\vert g(t) \vert \leq \varepsilon \) for all t. Then we have
Let \(v\in C_{\mathbb{R}}([0,T])\) be the unique solution of (12). Then v is given by
Hence,
where
and \(\overline{\mathcal{G}}(\varepsilon ) \) is a constant dependent on ε. Let \(g(t,s)= \frac{\vert {\lambda }-1\vert }{{\lambda }} \frac{1}{\Gamma ({k}-{\theta })}+ \mathcal{L} \frac{(t-s)^{{\theta }}}{{\lambda }\Gamma ({k})} \) and
Then \(\vert u(t)-{v}(t)\vert \leq {\Delta } \varepsilon + \int _{0}^{t}g(t,s)(t-s)^{\alpha -{\theta }-1} \vert u(s)-{v}(t)\vert \,ds\). Note that
In view of Lemma 5, we get
Put \({c}=E_{{k}-{\theta }}(MT^{({ k}-{\theta })}\Gamma ({k}-{ \theta })) \). Note that the inequality \(\vert u(t)-{v}(t)\vert <{c}\varepsilon \) holds. Thus, boundary value problem (12) is Hyers–Ulam stable. □
5 Examples
Now, we provide two examples to illustrate our main results.
Example 1
Consider the boundary value problem
Put \({\lambda }=47/54\), \({k}=5/2\), \({\theta }={2.1}\), \({\gamma _{1}}=7/15\), \({\gamma _{2}}=1/8\), \({q_{1}}=3/4\), \({q_{2}}=5/3\), \(\delta _{1}=1/16 \), \({\delta _{2}}=5/12 \), and \(T=1/4\). Note that \(0<{\gamma _{1}}\), \({\gamma _{2}}<{0.47}={ k}-{\theta }\) and
with \(\mathcal{L}=1/16 \) and \(\vert \hat{\Upsilon }(t,u(t))\vert \leq t^{2}=\mathcal{V}(t) \). If \({\mu _{1}}=1/3\) and \({\mu _{2}}=3/4\), then
Hence, \(\mathcal{L}\mathcal{W}_{2}+\mathcal{W}_{1}\approx {0.6808}<1\). Now, by using Theorem 8, problem (13) has a unique solution. If \({\mu _{1}}=1\) and \({\mu _{2}}=1\), then \(g(t,s)=\frac{\vert {\lambda }-1\vert }{{\lambda }} \frac{1}{\Gamma ({k}-{\theta })}+ \mathcal{L} \frac{(t-s)^{{\theta }}}{{\lambda }\Gamma ({k})}\). Note that
Now, by using Theorem 12, problem (2) is Hyers–Ulam stable.
Example 2
Consider the boundary value problem
Put \({\lambda }=40/45\), \({k}=13/5\), \({\theta }={2.01}\), \({\gamma _{1}}=7/88\), \({\gamma _{2}}=3/100\), \({q_{1}}=5/4\), \({q_{2}}=23/33\), \(\delta _{1}=21/156 \), \(\delta _{2}=55/122 \), and \(T=\frac{1}{4}\). Note that \(0<{\gamma _{1}}\), \({\gamma _{2}}<{0.59}={ k}-{\theta }\) and
Assume that \({\mu _{1}}=11/33\) and \({\mu _{2}}=9/13\). Then we have
and \(\vert \hat{\Upsilon }(t,u(t)) \vert = \vert \frac{1}{t^{2}+5} ( \frac{u^{2}(t)}{\vert u(t)\vert +1}+4 ) \vert \leq \frac{1}{t^{2}+5}(\vert x\vert +4)\). Put \(\Phi (t)=\frac{1}{t^{2}+5}\) and \(\Psi (|u|)=\vert x\vert +4 \) and choose \({\mathcal{Q}} > {379.5499} \) such that
Now, by using Theorem 10, problem (14) has at least one solution.
6 Conclusion
As many researchers would like to investigate the stability notion of different boundary value problems, this can be a motivation for us to study the stability of complicated systems supplemented with general boundary conditions. Hence, our main goal in the present manuscript is to obtain some existence criteria of a new general boundary value problem including 2-term fractional differential equation which contains multi-order Riemann–Liouville fractional derivatives and integrals. In the sequel, we check Hyers–Ulam stability of the proposed problem in the special case \({\mu _{1}}=1\) and \({\mu _{2}}=1\). Finally, we provide two illustrative examples to support our theoretical findings. This work can be an introduction for other researchers to study mentioned notions for numerous fractional multi-order modelings in the future.
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The first and second authors were supported by University of Kasdi Merbah. The third and fourth authors were supported by Azarbaijan Shahid Madani University. The authors express their gratitude to dear unknown referees for their helpful suggestions which improved the final version of this paper.
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Ben Chikh, S., Amara, A., Etemad, S. et al. On Hyers–Ulam stability of a multi-order boundary value problems via Riemann–Liouville derivatives and integrals. Adv Differ Equ 2020, 547 (2020). https://doi.org/10.1186/s13662-020-03012-1
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DOI: https://doi.org/10.1186/s13662-020-03012-1