Ulam stability results to a class of nonlinear implicit boundary value problems of impulsive fractional differential equations

In this paper, we derive some sufficient conditions which ensure the existence and uniqueness of a solution for a class of nonlinear three point boundary value problems of fractional order implicit differential equations (FOIDEs) with some boundary and impulsive conditions. Also we investigate various types of Hyers–Ulam stability (HUS) for our concerned problem. Using classical fixed point theory and nonlinear functional analysis, we obtain the required conditions. In the last section we give an example to show the applicability of our obtained results.

Differential equations of fractional order have been attracted the attention of researchers in the last few decades. It is due to the fact that fractional order derivatives provide power tools for the description of memory and hereditary characteristics of different processes and materials in various fields of science and engineering, (see [1,2,3,4]).

The impulsive phenomenon, which is a sudden and discontinuous change, is naturally observed in many physical systems. We model and describe such type of evolutionary processes via differential equations with some impulsive conditions. Significant and enormous number of applications of impulsive differential equations can be traced in mechanics, engineering, medicine, ecology, etc.; see for instance [5,6,7]. In the literature, the integer-order impulsive differential equations corresponding to initial and boundary conditions have been investigated extensively; see [8,9,10,11,12] and the references cited therein. There are many evolutionary processes related to pharmacotherapy, hemodynamics equilibrium of a person, introduction of bloodstream in the body and problems related to economical and national income, which cannot be accurately described by classical implicit impulsive differential equations. In such a situation the fractional order implicit impulsive differential equations are proved as powerful tools. The existence theory of the aforesaid problems have been extensively addressed in many articles; see [13, 14] and the references therein.

On the other side stability analysis, which is so much important from a numerical and optimization point of view, has been attracted the attention of researchers. So far various concepts of stability analysis, including Laypunov stability [15, 16], Mittag-Leffler stability [17], exponential stability [18] and Hyers–Ulam stability, have been introduced. Among all these concepts, Hyers–Ulam type stability analysis has been considered a relatively easy and simple way of studying the stability of solutions to fractional order implicit differential equations (FOIDEs). Ulam and Hyers introduced this concept of stability analysis in the mid of 19th century for functional problems; see [19, 20]. Many mathematicians generalized this concept in different directions; see [21,22,23,24,25]. For recent contribution on this area we refer to the work in [26, 27].

In this paper we study existence and uniqueness of solution as well as stability analysis to the following problem:

where the notation \({}_{0}^{C}\mathrm{D}_{t_{i}}^{\rho}\) stands for Caputo fractional derivative of order \(\rho\in(1, 2]\), \(\mathrm{J}=[0, 1]\), and \(\mathrm{F}: \mathrm{J}\times\mathrm{R}^{2}\rightarrow\mathrm{R}\) is a continuous function. Further, the nonlinear functions \(\mathrm{I}_{i},\tilde {\mathrm{I}}_{i} : \mathrm{R}\rightarrow\mathrm{R}\), are also continuous for \(i=1,2,\ldots,m\) and \(\Delta z(t)|_{t=t_{i}}=z(t^{+}_{i})-z(t^{-}_{i})\), \(\Delta z'(t)|_{t=t_{i}}=z'(t^{+}_{i})-z'(t^{-}_{i})\), where \(z(t^{+}_{i})\) and \(z(t^{-}_{i})\) represent the right and left-hand limit of the function \(z(t)\), respectively, at \(t=t_{i}\). Also, \(0=t_{0}< t_{1}< t_{2}<\cdots<t_{m}<t_{m+1}=1\), \(m\in\mathbb{Z}^{+}\), where \(\mathbb{Z}^{+}\) is the set of positive integers.

We recall some well-known results, definitions and theorems needed in this study. Splitting the interval J into sub intervals \([0,t_{1}], (t_{1},t_{2}], (t_{2},t_{3}],\ldots,(t_{p-1},t_{p}], (t_{m},1]\), and denote these sub intervals by \(\mathrm{J}_{0}, \mathrm{J}_{1}, \mathrm{J}_{2}, \ldots ,\mathrm{J}_{m-1}, \mathrm{J}_{m}\), respectively. Let \(\acute{\mathrm {J}}=\mathrm{J}\setminus\{t_{1},t_{2},t_{3},\ldots,t_{m}\}\). We define the space \(\mathrm{E}=PC(\mathrm{J},\mathrm{R})=\{z:\mathrm{J}\rightarrow\mathrm {R}:z\in C(\mathrm{J}_{i},\mathrm{R}), \mbox{and }z(t_{i}^{+}), z(t_{i}^{-})\mbox{ exist, for } i=1,2,\ldots,m\}\). Obviously \((\mathrm{E},\|z\|_{\mathrm{E}})\) is a Banach space with the norm given by \(\|z\|_{\mathrm{E}}=\max\{|z(t)|:t\in \mathrm{J} \}\).

Definition 1

([2])

The Caputo fractional derivative of a function \(z: (0,\infty)\rightarrow\mathrm{R}\), is defined as

where \(k=[\rho]+1\) and \([\rho]\) represents the integer part of the real number ρ.

Definition 2

([3])

The fractional order (\(0<\rho<\infty\)) integral of a function \(z\in L^{1}([0,T], \mathrm{R}^{+})\) is defined as

such that the right side is point-wise defined on \(\mathrm{R}^{+}\).

Lemma 1

([28])

For \(\rho>0\), the given result holds

Lemma 2

([28])

For \(\rho>0\), the differential equation \({{}_{0}^{C}\mathrm{D}_{t}^{\rho}} z(t)=h(t)\), has the following solution:

where \(k=[\rho]+1\).

Theorem 1

([2])

Let \(\rho>0\), then

where \(e_{i}\in\mathrm{R}\), \(i=0,1,2,3,\ldots,k-1\), \(k=[\rho]+1\).

We give the following three sets of inequalities.

If \(z \in\mathrm{E}\), then, for some constants \(\varphi>0\), \(\epsilon>0\) with a nondecreasing function \(\theta:\mathrm{J}\rightarrow\mathrm{R}\), the results given below hold for \(i=1,2,\ldots,m\):

Definition 3

([25])

The problem (1) is known to be UH stable if for \(\epsilon>0\) there exists a constant \(\mathbf{C}_{m,\rho}>0\) such that, for every solution \(\bar{z}\in\mathrm{E}\) of the inequality (2), one has a unique solution \(z\in\mathrm{E}\) to problem (1) satisfying

Definition 4

([25])

The problem (1) is known to be GHU stable if for every solution \(\bar{z}\in\mathrm{E}\) of the inequality (3) and \(\epsilon>0\), with a constant \(\psi_{m,\rho}\in C(\mathrm{R}^{+},\mathrm{R}^{+})\), there is unique solution \(z\in \mathrm{E}\) of problem (1) satisfying

Definition 5

([25])

The problem (1) is known to be HUR stable corresponding to \((\theta,\varphi)\) if for every \(\epsilon>0\) there exists a real number \(\mathbf{C}_{m,\rho,\theta}>0\), such that, for any solution \(\bar{z}\in\mathrm{E}\) of the inequality (4), one has a unique solution \(z\in\mathrm{E}\) of problem (1) satisfying

Definition 6

([25])

The problem (1) is known to be GHUR stable with respect to \((\theta,\varphi)\), if there exists a constant \(\mathbf{C}_{m,\rho,\theta}>0\), such that, for each solution \(\bar{z}\in \mathrm{E}\) of the inequality (3), one has a solution \(z\in \mathrm{E}\) of problem (1) satisfying

Remark 1

The function \(z\in\mathrm{E}\) is called a solution for the inequality (2) if one has a function \(\phi\in\mathrm{E}\) together with a sequence \(\phi_{i}\), \(i=1,2,\ldots,m\), depending on z such that

1. (i)

   \(|\phi(t)|\leq\epsilon\), \(|\phi_{i}|\leq\epsilon\), \(t\in \mathrm{J}_{i}\), \(i=1,2,\ldots,m\);

2. (ii)

   \({}_{0}^{C}\mathrm{D}_{t_{i}}^{\rho}z(t) = \mathrm{F}(t, z(t), {}_{0}^{C}\mathrm{D}_{t_{i}}^{\rho}z(t)) +\phi(t)\), \(t\in\mathrm {J}_{i}\), \(i=1,2,\ldots,m\);

3. (iii)

   \(\Delta z(t)|_{t=t_{i}}=\mathrm{I}_{i}(z(t_{i}))+\phi_{i}\), \(t\in\mathrm{J}_{i}\), \(i=1,2,\ldots,m\);

4. (iv)

   \(\Delta z'(t)|_{t=t_{i}}=\tilde{\mathrm{I}}_{i}(z(t_{i}))+\phi _{i}\), \(t\in\mathrm{J}_{i}\), \(i=1,2,\ldots,m\).

Remark 2

A function \(z\in\mathrm{E}\) is a solution of the inequality (4) if one has a function \(\phi\in\mathrm{E}\) and a sequence \(\phi_{i}\), \(i=1,2,\ldots,m\) depending on z with:

1. (i)

   \(|\phi(t)|\leq\epsilon\theta(t)\), \(|\phi_{i}|\leq\epsilon \varphi\), \(t\in\mathrm{J}_{i}\), \(i=1,2,\ldots,m\);

2. (ii)

   \({}_{0}^{C}\mathrm{D}_{t_{i}}^{\rho}z(t) = \mathrm{F}(t, z(t), {}_{0}^{C}\mathrm{D}_{t_{i}}^{\rho}z(t)) +\phi(t)\), \(t\in\mathrm {J}_{i}\), \(i=1,2,\ldots,m\);

3. (iii)

   \(\Delta z(t)|_{t=t_{i}}=\mathrm{I}_{i}(z(t_{i}))+\phi_{i}\), \(t\in\mathrm{J}_{i}\), \(i=1,2,\ldots,m\);

4. (iv)

   \(\Delta z'(t)|_{t=t_{i}}=\tilde{\mathrm{I}}_{i}(z(t_{i}))+\phi _{i}\), \(t\in\mathrm{J}_{i}\), \(i=1,2,\ldots,m\).

Similarly one can state such a remark for the inequality (3).

Theorem 2

(Schaefer’s fixed point theorem [29])

Let E be a Banach space and \(\mathscr{T} : \mathrm{E}\rightarrow \mathrm{E}\) is completely continuous operator and the set \(\mathrm{W} = \{z \in \mathrm{E} : z = \eta\mathscr{T}z, 0<\eta<1\}\) is bounded. Then \(\mathscr{T}\) has a fixed point in E.

Lemma 3

Let \(\rho\in(1, 2]\), \(\sigma:\mathrm{J}\rightarrow\mathrm{R}\) be a continuous function, then the function \(z\in\mathrm{E}\) is the solution to the following problem:

if and only if z satisfies the following integral equation:

where

Proof

Assume that, for \(t\in\mathrm{J}_{0}\), z is a solution of (5). Then, by Lemma 1, there exist \(a_{1},a_{2}\in\mathrm{R}\) such that

which also yields

Let for \(t\in\mathrm{J}_{1}\), we have \(d_{1},d_{2}\in\mathrm{R}\), with

This leads to

Due to impulsive conditions, we have

we have

Thus (9) implies

Similarly for \(t\in\mathrm{J}_{k}\), one has

Using the given boundary conditions in (7), (8) and (10), we obtain \(a_{1}+a_{2}=0\) and

Therefore, in view of \(z(1)=-z'(\varrho)\) and \(a_{1}+a_{2}=0\), we get

Inserting these values of \(a_{1}\) and \(a_{2}\) in (7) and (10), respectively, with \(\mathcal{A}=a_{2}\), we get (6). Conversely if (6) has a solution z, then it is obvious that the solution \(z(t)\) satisfies problem (5) under the given conditions. □

Corollary 1

In view of Lemma 3, our problem (1) has the following solution:

where

We use the notation \(\vartheta_{z}(t)=\mathrm{F}(t, z(t), {}_{0}^{C}\mathrm {D}_{t_{i}}^{\rho}z(t))\).

To transform our problem to a fixed point problem, we define the operator \(\mathscr{T} : \mathrm{E}\rightarrow\mathrm{E}\) by

Obviously, the fixed points of \(\mathscr{T}\) are the solutions of problem (1).

We assume the following hypotheses for \(i=1,2,\ldots,m\).

(H₁):

The nonlinear function \(\mathrm{F} : [0,1]\times\mathrm {R}^{2}\rightarrow\mathrm{R}\) is continuous;

(H₂):

let us have constants \(K>0\), \(L\in(0, 1)\), which satisfy

$$\bigl\vert \mathrm{F}(t,z,\bar{z})-\mathrm{F}(t, u,\bar{u}) \bigr\vert \leq K \bigl\vert z(t)-u(t) \bigr\vert +L \bigl\vert \bar{z}(t)-\bar{u}(t) \bigr\vert ; $$

(H₃):

the relation \(|\mathrm{I}_{i}(z(t_{i}))-\mathrm{I}_{i}(\bar {z}(t_{i}))|\leq b|z(t_{i})-\bar{z}(t_{i})|\), holds with \(b>0\);

(H₄):

the relation \(|\tilde{\mathrm{I}}_{i}(z(t_{i}))- \tilde{\mathrm{I}}_{i}(\bar{z}(t_{i}))|\leq b^{*}|z(t_{i})-\bar{z}(t_{i})|\), holds with \(b^{*}>0\);

(H₅):

there exist functions \(p, q, r \in C(\mathrm{J},\mathrm {R}^{+})\), with

$$\bigl\vert \mathrm{F}\bigl(t, z(t), _{0}^{C} \mathrm{D}_{t_{i}}^{\rho}z(t)\bigr) \bigr\vert \leq p(t)+q(t) \vert z \vert +r(t) \bigl\vert _{0}^{C} \mathrm{D}_{t_{i}}^{\rho}z(t) \bigr\vert , \quad \mbox{for }t \in\mathrm {J}, z\in\mathrm{E}, $$

such that \(r^{*}=\sup_{t\in\mathrm{J}}|r(t)|<1\);

(H₆):

under the continuity of \(\mathrm{I}_{i},\tilde {\mathrm{I}}_{i}:\mathrm{R}\rightarrow\mathrm{R}\) there exist some constants \(M^{*}, N^{*}, F^{*}, G^{*}>0\), with \(|\mathrm{I}_{i}(z)|\leq M^{*}|z|+N^{*}\) and \(|\tilde{\mathrm{I}}_{i}(z)|\leq F^{*}|z|+G^{*}\), for each \(z\in\mathrm{R}\), \(i=1,2,\ldots,m\).

Theorem 3

If the hypotheses (H₁)–(H₆) hold then the considered problem (1) has at least one solution.

Proof

This proof consists of a number of steps:

Step 1: To show that \(\mathscr{T}\) is continuous, take \(\{ z_{n}\}\) to be a sequence such that \(z_{n}\rightarrow z\in\mathrm{E}\). Then, corresponding to every \(t\in\mathrm{J}\), we take

where \(\vartheta_{z,n}, \vartheta_{z}\in C(\mathrm{J},\mathrm{R})\) satisfy the functional equations

respectively. By (H₂), we get

Here \(z_{n}\rightarrow z\) as \(n\rightarrow\infty\) implies \(\vartheta _{z,n}(t)\rightarrow\vartheta_{z}(t)\) as \(n\rightarrow\infty\), for each \(t\in\mathrm{J}\). Also as every convergent sequence is bounded and we let there exist a real constant such that, for each \(t\in\mathrm{J}\), we have and , then

and

The functions , , and are integrable for each \(t\in \mathrm{J}\) on \([0,t]\). Also since F, I, \(\bar{\mathfrak{I}}\) are continuous, hence by Lebesgue dominated convergent theorem, from (11), we have

Hence

Therefore, the operator T is continuous.

Step 2: Next we show that \(\mathscr{T}\) maps bounded sets into bounded sets. Indeed, we just need to show that, for any \(\lambda>0\), there exists a constant \(\varpi>0\) such that, for every \(z\in\mathfrak{D}_{\lambda}=\{ z\in\mathrm{E} : \|z\|_{PC}\leq\lambda\}\), one has \(\|\mathscr{T}z\| _{PC}\leq\varpi\). For every \(t\in\mathrm{J}\), we obtain

where \(\vartheta_{z}\) is given in (12). Using (H₅), for each \(t\in\mathrm{J}\) and using \(p^{*}=\sup_{t\in \mathrm{J}}|p(t)|\), \(q^{*}=\sup_{t\in\mathrm{J}}|q(t)|\), we have

which yields

Thanks to (15), the inequality (14) yields

which further gives

Step 3: To show that \(\mathscr{T}\) is equi-continuous, let \(\mathfrak{D}_{\lambda}\subseteq\mathrm{E}\), then, for \(z\in\mathfrak{D}_{\lambda}\) and \(t_{1}\), \(t_{2}\in\mathrm{J}\) with \(t_{1}< t_{2}\), we get

Hence

Thanks to Ascoli–Arzelà theorem, the operator \(\mathscr{T} : \mathrm{E} \rightarrow\mathrm{E}\) is completely continuous.

Step 4: Finally, we show that the set \(\mathrm{W}=\{z \in\mathrm{E} : z = \eta\mathscr{T}z,\mbox{for some }0<\eta<1\}\) is bounded, such that, for \(z\in\mathrm{W}\), and \(z= \eta\mathscr{T}z\), with \(0<\eta<1\), hold. Then for every \(t \in\mathrm{J}\), we take

By using (15) and \(0<\eta<1\) (16) implies that

This further gives

Thus, we conclude that the set W is bounded. Hence as a consequence of Schaefer’s fixed point theorem \(\mathscr{T}\) has at least one fixed point which is the solution of problem (1). □

Theorem 4

The boundary value problem (BVP) (1) has a unique solution under the hypotheses (H₁)–(H₄) and the inequality

Proof

Let \(z, \bar{z}\in\mathrm{E}\) and \(t\in\mathrm{J}\), then one has

where

With the use of (H₂), one has

Therefore, using (20) in (18), we obtain

Therefore, we get

Thus in view of Banach’s contraction principle, problem (1) has a unique solution. □

In this section we investigate results concerning the Hyers–Ulam stability to the problem (1).

Theorem 5

If the hypotheses (H₁)–(H₄) together with the inequality (17) are satisfied then the proposed problem (1) is Hyers–Ulam stable and generalized Hyers–Ulam stable.

Proof

Corresponding to any solution \(\bar{z}\in E\) of the inequality (2) let \(z\in E\) be the unique solution to the given problem

Then, inview of Lemma 3, we have

Further if z̄ is the solution of inequality (2) and using Remark 1, we get

The solution of (21) is

Hence, for every \(t\in\mathrm{J}_{i}\), one has

Hence by (H₁)–(H₄) and using (20) along with (i) of Remark 1, one has

This yields

Hence we have

where

Thus the solution of (1) is HU stable. Also by setting \(\psi (\epsilon)=\mathbf{C}_{m,\rho}\epsilon\); \(\psi(0)=0\), the solution of (1) becomes GHU stable. □

Assume that:

(H₈):

For a nondecreasing function \(\theta\in C(\mathrm {J},\mathrm{R})\), there exists \(\beta_{\theta}>0\), such that, for any \(t\in\mathrm{J}\)

$$I^{\rho}\theta(t)\leq\beta_{\theta}\theta(t);\quad \text{consequently}\quad I^{\rho -1}\theta(t)\leq\beta_{\theta}\theta(t). $$

Theorem 6

If the hypotheses (H₁)–(H₄), (H₈) and the inequality (17) are satisfied, then problem (1) is HUR stable with respect to \((\theta,\varphi)\) and consequently GHUR stable.

Proof

We address for any solution \(\bar{z}\in\mathrm{E}\) of inequality (4) and for unique solution z the given problem

From the proof of Theorem 5, we get

Thanks to (H₁)–(H₄), (20) and part (i) of Remark 2, we have

This finally yields

where

Hence the solution to problem (1) is HUR stable and consequently GHUR stable. □

Consider the following implicit BVP of FODEs with impulsive conditions:

Example 1

In this example, we see that \(\rho=\frac{3}{2}\), \(\varrho=\frac{1}{2}\), \(m=1\). Set

The continuity of F is obvious.

For \(z, \bar{z}\in\mathrm{E}\) and \(\delta_{z}, \delta_{\bar{z}}\in C(\mathrm{J}, \mathrm{R})\), \(t\in\mathrm{J}\),

This satisfies (H₂) with \(K=L=\frac{1}{20}\). Further, for \(t_{1}=\frac {1}{3}\), let

For any \(z, \bar{z}\in\mathrm{E}\), we have

and

These satisfy (H₃) and (H₄) with \(b=\frac{1}{60}\), \(b^{*}=\frac {1}{45}\).

Also

In view of Theorem 4, the uniqueness of solution to (22) follows. Thanks to Theorem 5 analogously one can see that the solution of problem (22) is HU stable and consequently GHU stable.

Further, assuming \(\theta(t)=1\), we have

Thus (H₈) holds with \(\beta_{\theta}=\frac{1}{3\sqrt{\Pi}}\) and \(\theta (t)=1\), therefore, in view of Theorem 6, the solution of (22) is HUR stable corresponding to \((\theta,\varphi)\) and consequently GHUR stable with respect to \((\theta,\varphi)\).

By successful applications of nonlinear analysis and classical fixed point theory, we have developed adequate conditions under which the proposed class of implicit impulsive FODEs has at least one solution. Further, some useful results were also obtained that ensure different kinds of HUS which is important for the nonlinear problems from optimization and numerical point of view and plays a main role in numerical solutions where the exact solution is quite difficult.

HUS:

Hyers–Ulam stability

GHUS:

Generalized Hyers–Ulam stability

HURS:

Hyers–Ulam–Rassias stability

GHURS:

Generalized Hyers–Ulam–Rassias stability

We are really thankful to the reviewers for their useful suggestions and corrections.

This research work has been financially supported by Prof. Dumitru Baleanu of the Department of Mathematics, Cankaya University, Etimesgut/Ankara, Turkey.

Authors and Affiliations

1. Department of Mathematics, University of Malakand, Dir(L), Khyber Pakhtunkhwa, Pakistan

   A. Ali & K. Shah

2. Department of Mathematics, Cankaya University, Ankara, Turkey

   D. Baleanu

Contributions

All authors equally contributed to this manuscript and approved the final version.

Corresponding author

Correspondence to A. Ali.

Competing interests

The authors declare that they have no competing interests.

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