Nonlinear fractional differential equation involving two mixed fractional orders with nonlocal boundary conditions and Ulam–Hyers stability

In this paper, we study a nonlinear fractional differential equation involving two mixed fractional orders with nonlocal boundary conditions. By using some new techniques, we introduce a formula of solutions for above problem, which can be regarded as a novelty item. Moreover, under the weak assumptions and using Leray–Schauder degree theory, we obtain the existence result of solutions for above problem. Furthermore, we discuss the Ulam–Hyers stability of the above fractional differential equation. Three examples illustrate our results.

The fractional derivatives provide an excellent tool to describe the memory and hereditary properties of various materials and processes. The fractional differential equations can model some engineering and scientific disciplines in the fields of physics, chemistry, electrodynamics of complex medium, polymer rheology, etc. [1–12]. In particular, the forward and backward fractional derivatives provide an excellent tool for the description of some physical phenomena such as the fractional oscillator equations and the fractional Euler–Lagrange equations [3–7, 13]. Recently, many researchers have focused on the existence of solutions for boundary value problems involving both the right Caputo and the left Riemann–Liouville fractional derivatives (see [6, 7, 13], and the references cited therein).

Moreover, the Ulam stability problem [14] has attracted many researchers (see [15, 16] and the references therein). Recently, the Ulam–Hyers stability of fractional differential equations has been gaining much importance and attention [17–20].

Sousa et al. [19] studied the ψ-Hilfer fractional derivative and the Hyers–Ulam–Rassias and Hyers–Ulam stability of the Volterra integrodifferential equation:

where \(\alpha \in (0,1), \beta \in [0,1], \gamma \in [0,1)\), σ is a constant, \({}^{H}D_{0^{+}}^{\alpha,\beta;\psi }\) is the ψ-Hilfer fractional derivative and \(I_{0^{+}}^{1-\gamma }\) is the ψ-Riemann–Liouville fractional integral.

Chalishajar et al. [20] studied the existence, uniqueness, and Ulam–Hyers stability of solutions for the coupled system of fractional differential equations with integral boundary conditions:

where \(\alpha, \beta \in (1,2]\), \(p, q, \tilde{p}, \tilde{q}\geq 0\) are constants, \(a_{1}, a_{2}, \tilde{a}_{1}, \tilde{a}_{2}\) are continuous functions.

In this paper, we study the following boundary value problem of fractional differential equation with two different fractional derivatives:

where \(\alpha, \beta, \alpha +\beta \in (0,1)\), \(\lambda >0\), \(\gamma >1\), \(\rho >0\), \(\alpha +\rho >1\) and \(\xi _{i}, \eta \in (0,1](i=1,2,\ldots,m)\). \({}^{c}D^{\beta }_{1^{-}}\) is the right-sided Caputo fractional derivative, \({}^{L}D^{\alpha }_{0^{+}}\) is the left-sided Riemann–Liouville fractional derivative, \({I_{0^{+}}^{1-\alpha }}\) is the left-sided Riemann–Liouville fractional integral, \({}^{\rho }{I_{0^{+}}^{\gamma }}\) is a Katugampola fractional integral.

Different from the previous results, the boundary conditions considered in this paper include the nonlocal Katugampola fractional integral, moreover, under the weak assumptions and using Leray–Schauder degree theory, we obtain the existence result of solutions for the above problem (Theorem 5.3). However, to the best of our knowledge, few papers can be found in the literature dealing with the existence result and the Ulam–Hyers stability of differential equation involving the forward and backward fractional derivatives.

The rest of this paper is organized as follows. In Sect. 2, we collect some concepts of fractional calculus. In Sect. 3, we prove some properties of classical and generalized Mittag-Leffler functions. In Sect. 4, we present the definition of solution to (1.1)–(1.2). In Sect. 5, we obtain the existence and uniqueness of solutions to problem (1.1)–(1.2). In Sect. 6, we present Ulam–Hyers stability result for Eq. (1.1). Three examples are given in Sect. 7 to demonstrate the applicability of our result.

In this section, we introduce some notations and definitions of fractional calculus. Throughout this paper, we denote by \(C(J,\mathbb{R})\) the Banach space of all continuous functions from J to \(\mathbb{R}\), by \(AC([a,b], \mathbb{R})\) the space of absolutely continuous functions on \([a,b]\). \(\varGamma (\cdot )\) and \(B(\cdot, \cdot )\) are the gamma and beta functions, respectively.

Definition 2.1

([3, 4])

The left-sided and the right-sided fractional integrals of order δ for a function \(x(t)\in L^{1}\) are defined by

and

respectively.

Definition 2.2

([3, 4])

If \(x(t)\in AC([a,b],\mathbb{R})\), then the left-sided Riemann–Liouville fractional derivative \({}^{L}{D_{a^{+}}^{\delta }}x(t)\) of order δ exists almost everywhere on \([a,b]\) and can be written as

Definition 2.3

([3, 4])

If \(x(t)\in AC([a,b],\mathbb{R})\), then the right-sided Caputo fractional derivative \({}^{c}{D_{b^{-}}^{\delta }}x(t)\) of order δ exists almost everywhere on \([a,b]\) and can be written as

Definition 2.4

([21])

For \(\rho, q>0\), the Katugampola fractional integral of \(y(t)\) is defined by

In this section, we prove some properties of the Mittag-Leffler functions.

Definition 3.1

([3, 4])

For \(\mu, \nu >0, z\in \mathbb{R} \), the classical Mittag-Leffler function \(E_{\mu }(z)\) and the generalized Mittag-Leffler function \(E_{\mu,\nu }(z)\) are defined by

Clearly, \(E_{\mu,1}(z)=E_{\mu }(z)\).

Lemma 3.2

([4, 22])

Let\(\alpha \in (0, 1)\). Then the nonnegative functions\(E_{\alpha }\), \(E_{\alpha,\alpha }\), \(E_{\alpha,\alpha +1}\)have the following properties:

1. (i)

   For any\(t\in J\), \(E_{\alpha }(-\lambda t^{\alpha })\leq 1\), \(E_{\alpha,\alpha }(-\lambda t^{\alpha })\leq \frac{1}{\varGamma (\alpha )}\), \(E_{\alpha,\alpha +1}(-\lambda t^{\alpha })\leq \frac{1}{\varGamma (\alpha +1)}\).

2. (ii)

   For any\(t_{1}, t_{2}\in J\),

   $$\begin{aligned} &\bigl\vert E_{\alpha }\bigl(-\lambda t_{2}^{\alpha } \bigr)-E_{\alpha }\bigl(-\lambda t_{1}^{\alpha }\bigr) \bigr\vert =O\bigl( \vert t_{2}-t_{1} \vert ^{\alpha }\bigr), \quad\textit{as } t_{2}\rightarrow t_{1}, \\ &\bigl\vert E_{\alpha,\alpha }\bigl(-\lambda t_{2}^{\alpha } \bigr)-E_{\alpha,\alpha }\bigl(- \lambda t_{1}^{\alpha }\bigr) \bigr\vert =O\bigl( \vert t_{2}-t_{1} \vert ^{\alpha }\bigr), \quad\textit{as } t_{2}\rightarrow t_{1}, \\ &\bigl\vert E_{\alpha,\alpha +1}\bigl(-\lambda t_{2}^{\alpha } \bigr)-E_{\alpha,\alpha +1}\bigl(- \lambda t_{1}^{\alpha }\bigr) \bigr\vert =O\bigl( \vert t_{2}-t_{1} \vert ^{\alpha }\bigr), \quad\textit{as } t_{2}\rightarrow t_{1}. \end{aligned}$$

Lemma 3.3

Let\({\gamma,\mu,\nu,\lambda }>0, t>0\), \(0<\alpha, \beta <1\), then the following formulas are valid:

1. (i)

   \({\frac{d}{dt}[t^{\nu -1}E_{\mu, \nu }(-\lambda t^{\mu })]=t^{ \nu -2}E_{\mu,\nu -1}(-\lambda t^{\mu })}\) (\(\nu >1\)) and\({\frac{d}{dt}E_{\mu }(-\lambda t^{\mu })=-\lambda t^{\mu -1}E_{ \mu,\mu }(-\lambda t^{\mu })}\);

2. (ii)

   \({{I_{0^{+}}^{\gamma }}(s^{\nu -1}{E_{\mu,\nu }({- \lambda }s^{\mu })})(t)=\frac{1}{\varGamma (\gamma )}\int _{0}^{t}(t-s)^{ \gamma -1}s^{\nu -1}E_{\mu,\nu }(-\lambda s^{\mu })\,ds=t^{\gamma + \nu -1}{E_{\mu,{\gamma +\nu }}({-\lambda }t^{\mu })}}\);

3. (iii)

   \([{} ^{L}{D_{0^{+}}^{\nu }}s^{\beta -1}{E_{\alpha,\beta }(-{ \lambda }s^{\alpha })} ](t)=t^{\beta -\nu -1}{E_{\alpha, \beta -\nu }(-{\lambda }t^{\alpha })}, (\beta >\nu )\);

4. (iv)

   \([{} ^{c}{D_{1^{-}}^{\beta }} {}^{L}{D_{0^{+}}^{\alpha }}s^{\alpha }{E_{ \alpha,\alpha +1}(-{\lambda }s^{\alpha })} ](t)+{\lambda } [{} ^{c}{D_{1^{-}}^{\beta }}s^{\alpha }{E_{\alpha,\alpha +1}(-{ \lambda }s^{\alpha })} ](t)=0\);

5. (v)

   \([{} ^{c}{D_{1^{-}}^{\beta }} {}^{L}{D_{0^{+}}^{\alpha }}s^{\alpha -1}{E_{ \alpha,\alpha }(-{\lambda }s^{\alpha })} ](t)+{\lambda } [{} ^{c}{D_{1^{-}}^{\beta }}s^{\alpha -1}{E_{\alpha,\alpha }(-{ \lambda }s^{\alpha })} ](t)=0\);

6. (vi)

   \({ [{} ^{\rho }{I_{0^{+}}^{\gamma }}s^{\nu -1}{E_{ \alpha,\nu }(-{\lambda }s^{\alpha })} ](t) ={ \frac{t^{\gamma \rho +\nu -1}}{\rho ^{\gamma }\varGamma (\gamma )}}{\int _{0}^{1} s^{\frac{\nu -1}{\rho }}(1-s)^{\gamma -1} {E_{\alpha,\nu }(-{ \lambda }t^{\alpha }s^{\frac{\alpha }{\rho }})}} \,ds}\), \(\nu =\alpha \)or\(\nu =\alpha +1\).

Proof

It follows from the results in [3] that (i)–(iii) hold. Moreover,

Similarly, we have \({ [{} ^{L}{D_{0^{+}}^{\alpha }}s^{\alpha }{E_{\alpha, \alpha +1}(-{\lambda }s^{\alpha })} ](t)={E_{\alpha }(-{ \lambda }t^{\alpha })}}\). Furthermore, we get

This yields (iv). (v) can be obtained in a similar way. Clearly, for \(\nu =\alpha \) or \(\nu =\alpha +1\), the integral \({\int _{0}^{t} (1-\tau )^{\gamma -1} \tau ^{ \frac{\nu -1}{\rho }}{E_{\alpha,\nu }(-{\lambda }t^{\alpha }\tau ^{ \frac{\alpha }{\rho }})} \,d\tau }\) exists, then

Thus we have proved (vi). □

In this section, we present the formula of the solution to the problem (1.1)–(1.2).

Lemma 4.1

([3])

For\(\theta >0\), a general solution of the fractional differential equation\({}^{c}D_{1^{-}}^{\theta }u(t)=0\)is given by

where\(c_{i}\in \mathbb{R}, i=0,1,2,\ldots,n-1(n=[\theta ]+1)\), and\([\theta ]\)denotes the integer part of the real numberθ.

Similar to the arguments in [3], we can obtain the following result.

Lemma 4.2

For\(\alpha, \beta \in (0,1)\), \(h\in L^{1}(0,1)\), if\({}^{c}D_{1^{-}}^{\beta } ({} ^{L} D_{0^{+}}^{\alpha }+\lambda ) u(t)=h(t), t\in J\), then

Formally, by Lemma 4.1, for \(c_{0}\in \mathbb{R}\), we have \(({} ^{L} D_{0^{+}}^{\alpha }+\lambda ) u(t)=c_{0}+(I_{1^{-}}^{\beta }h)(t)\). Based on the arguments in Sect. 4.1.1 of [3], we obtain

We define \(C_{1-\alpha }([0,1],\mathbb{R})=\{u\in C(J,\mathbb{R}):t^{1-\alpha } u(t) \in C([0,1],\mathbb{R})\}\) with the norm \(\|u\|_{1-\alpha }=\max_{t\in [0,1]}t^{1-\alpha }|u(t)|\) and abbreviate \(C_{1-\alpha }([0,1],\mathbb{R})\) to \(C_{1-\alpha }\).

We need the following assumptions.

1. (H1)

   \(f:J\times \mathbb{R} \rightarrow \mathbb{R}\) satisfies \(f(\cdot,\omega ):J \rightarrow \mathbb{R}\) is measurable for all \(\omega \in \mathbb{R}\) and there exist \(L_{f}>0\) and \(\sigma \in [0,1)\) such that

   $$ \bigl\vert f(t,\omega )-f(t,\widetilde{\omega }) \bigr\vert \leq L_{f} \vert \omega - \widetilde{\omega } \vert ^{\sigma }. $$
2. (H2)

   \(M_{f}:=\sup_{t\in J}|f(t, 0)|<\infty \).

For convenience of the following presentation, we set

Since \({\int _{s}^{1}(\tau -s)^{\beta -1}\tau ^{\alpha -1}\,d \tau < \frac{s^{\alpha -1}}{\beta }}, {\int _{0}^{t}(t-s)^{ \alpha -1}s^{\alpha -1}\,ds=t^{2\alpha -1}B(\alpha, \alpha )\leq t^{ \alpha -1}B(\alpha, \alpha )}\) and

where \(\|u\|_{\sigma,1-\alpha }=\max_{t\in [0,1]}t^{1-\alpha }|u(t)|^{ \sigma }\), one can find

Lemma 4.3

For\(0< t_{1}<t_{2}\leq 1\),

Proof

By the mean value theorem and Lemma 3.2, we obtain

Then, using the inequality \(t_{2}^{\alpha }-t_{1}^{\alpha }\leq (t_{2}-t_{1})^{\alpha }\) and Eqs. (4.2), (4.7) and (4.8), we get

and

 □

Lemma 4.4

Assume that (H1) and (H2) hold. For\(u\in C_{1-\alpha }\), \(t\in J\), we have

1. (i)

   \((Gu)(t) \in {AC(J,\mathbb{R})}\);

2. (ii)

   \([{} ^{L}{D_{0^{+}}^{\alpha }}(Gu)(s) ](t) ={-\lambda }(Gu)(t)+{(I_{1^{-}}^{ \beta }f)(t)}\);

3. (iii)

   \([{} ^{c}{D_{1^{-}}^{\beta }} {}^{L}{D_{0^{+}}^{\alpha }}{(Gu)(s)} ](t)+{\lambda } [{} ^{c}{D_{1^{-}}^{\beta }}{(Gu)(s)} ](t)=f(t,u(t)) \);

4. (iv)

   \([{} ^{\rho }I_{0^{+}}^{\gamma }(Gu)(s) ](t) ={ \frac{t^{\gamma \rho }}{\rho ^{\gamma }\varGamma (\gamma )}\int _{0}^{1} (1-s)^{ \gamma -1}(Gu) (ts^{\frac{1}{\rho }})\,ds}\).

Proof

(i)–(iii) For every finite collection \(\{(a_{j},b_{j})\}_{1{\leq }j{\leq }n}\) on J with \(\sum_{j=1}^{n}(b_{j}-a_{j})\rightarrow 0\), using the inequalities \(b_{j}^{\alpha }-a_{j}^{\alpha }\leq (b_{j}-a_{j})^{\alpha }, j=1,2, \ldots,n\), and Eqs. (4.4)–(4.6), we arrive at

Then, \((Gu)(t)\) is absolutely continuous on J. Hence, for almost all \(t\in J\), \([ {}^{L} D_{0^{+}}^{\alpha }(Gu)(s) ](t)\) exists and from Lemma 3.3 it follows that

Furthermore,

(iv) It follows from (4.3) that \({}^{\rho }I_{0^{+}}^{\gamma }(Gu)(t)\) exists, and

 □

Lemma 4.5

Assume that (H1) and (H2) hold. A functionuis a solution of the following fractional integral equation:

if and only ifuis a solution of the problem (1.1)–(1.2), where

Proof

(Sufficiency) Let u be the solution of (1.1)–(1.2), Lemma 3.3, Lemma 4.2 and Lemma 4.4 imply

where \(c_{0},c_{1}\) are constants. Using the boundary value condition (1.2), we derive that \(c_{1}=u_{0}\) and

then

Now we can see that (4.9) holds.

(Necessity) Let u satisfy (4.9). From Lemma 3.3(iv), (v) and Lemma 4.4(iii), it follows that \([{}^{c}{D_{1^{-}}^{\beta }} {}^{L}{D_{0^{+}}^{\alpha }}u ](t)\) exists and \({}^{c}{D_{1^{-}}^{\beta }}({} ^{L}{D_{0^{+}}^{\alpha }}+\lambda )u(t)=f(t,u(t))\) for \(t\in J\). Clearly, the boundary value condition (1.2) holds and hence the necessity is proved. □

In this section, we deal with the existence and uniqueness of solutions to the problem (1.1)–(1.2).

Lemma 5.1

Let\(v\in C([0,1],\mathbb{R})\)satisfy the following inequality:

where\(a,b,c,d>0\)are constants. Then\(|v(t)|\leq M\), whereMis the only positive solution of the equation

Proof

Let \(\overline{m}=\max_{t\in [0,1]}|v(t)|\), using the following estimates:

we conclude that

thus \(\overline{m}\leq M\). □

Lemma 5.2

Let\(\widetilde{v}\in C([0,1],\mathbb{R})\)satisfy the following inequality:

where\(\widetilde{a},\widetilde{b},\widetilde{c}>0\)are constants. If\((\widetilde{a}+\widetilde{b}\sum_{i=1}^{m} \xi _{i}^{ \alpha -1}+\widetilde{c}\eta ^{\alpha -1}B(\gamma, \frac{\alpha -1+\rho }{\rho }) ) \frac{B(\alpha,\alpha )}{\beta }<1\), then\(\widetilde{v}(t)\equiv 0\).

Proof

Let \(\widetilde{m}=\max_{t\in [0,1]}|\widetilde{v}(t)|\), from the following inequalities:

we deduce that

thus \(\widetilde{m}= 0\). □

Next, we study the existence result of solutions for (1.1)–(1.2). For convenience of the following presentation, we set

Theorem 5.3

Assume that (H1) and (H2) are satisfied, then the problem (1.1)–(1.2) has at least one solution\(u\in C_{1-\alpha }\).

Proof

We consider an operator \(\mathcal{F}: C_{1-\alpha }\rightarrow C_{1-\alpha }\) defined by

Clearly, \(\mathcal{F}\) is well defined, and the fixed point of \(\mathcal{F}\) is the solution of the problem (1.1)–(1.2).

Let \(\{u_{n}\}\) be a sequence such that \(u_{n}\rightarrow u\) in \(C_{1-\alpha }\), then there exists \(\varepsilon >0\) such that \(\|u_{n}-u\|_{1-\alpha }<\varepsilon \) for n sufficiently large. By (H1), we have \(|f(t,u_{n}(t))-f(t,u(t))|\leq L_{f}t^{\sigma (\alpha -1)} \varepsilon ^{\sigma } \). Moreover, from (5.1)–(5.3), we have

furthermore,

Now we see that \(\mathcal{F}\) is continuous.

For \(0< t_{1}< t_{2}<1\), from (4.4)–(4.6), we find

moreover, according to (4.3) and Lemma 3.2, we know that \(|(Qu)(t_{2})-(Qu)(t_{1})|\rightarrow 0\) and \(|(Pu)(t_{2})-(Pu)(t_{1})|\rightarrow 0\) as \(t_{2}\rightarrow t_{1}\). Hence the operator \(\mathcal{F}\) is equicontinuous.

We just need to prove the existence of at least one solution \(u\in C_{1-\alpha }\) satisfying \(u=\mathcal{F}u\).

Hence, we show that \(\mathcal{F}: \overline{B}_{R}\rightarrow C_{1-\alpha }\) satisfies the condition

where \(B_{R}=\{u\in C_{1-\alpha }:t^{1-\alpha } |u(t)|< R, R>0\}\). We define \(H(\theta, u) =\theta \mathcal{F}u, u\in C_{1-\alpha }, \theta \in [0,1]\). By the Arzela–Ascoli theorem, a continuous map \(h_{\theta }\) defined by \(h_{\theta }(u)= u-H(\theta, u)=u-\theta \mathcal{F}u\) is completely continuous.

If (5.6) is true, then the Leray–Schauder degrees are well defined and from the homotopy invariance of topological degree, it follows that

Let \(v(t)=t^{1-\alpha }u(t)\), we obtain the following estimate:

and hence

then

Applying (5.2) and (5.3), we obtain

where

Then from Lemma 5.1, we find \(\|u\|_{1-\alpha }\leq \widetilde{M}\), where M̃ satisfies

Set \(R=\widetilde{M}+1\), then (5.6) holds. This completes the proof. □

Next, we study the uniqueness of solution, for this purpose, we give the following assumptions.

(H1′):

\(f:J\times \mathbb{R} \rightarrow \mathbb{R}\) satisfies \(f(\cdot,\omega ):J \rightarrow \mathbb{R}\) is measurable for all \(\omega \in \mathbb{R}\) and there exist \(L'_{f}, \widetilde{M}_{f}>0\) and \(\widetilde{\sigma }\in [0,1)\) such that

$$ \bigl\vert f(t, \omega ) \bigr\vert \leq L'_{f} \vert \omega \vert ^{\widetilde{\sigma }} + \widetilde{M}_{f}. $$

(H2′):

There exists a constant \(\widetilde{L}_{f}>0\) such that

$$ \bigl\vert f(t, \omega )-f(t, \widetilde{\omega }) \bigr\vert \leq \widetilde{L}_{f} \vert \omega -\widetilde{\omega } \vert ,\quad \text{for } \omega, \widetilde{\omega }\in \mathbb{R}, t\in J. $$

Theorem 5.4

Assume that (H1′) and (H2′) hold, then the problem (1.1)–(1.2) has a unique solution\(u\in C_{1-\alpha }\), provided that

Proof

By (H1′) and the proof of Theorem 5.3, it is not difficult to see that (1.1)–(1.2) has a solution \(u(\cdot )\in C_{1-\alpha }\). Let \(\widetilde{u}(\cdot )\) be another solution of the problem (1.1)–(1.2). According to (H2′), we find

Let \(\tilde{v}(t)=t^{1-\alpha }(u(t)-\widetilde{u}(t))\), then

Furthermore, from Lemma 5.2, it follows that \(u(t)-\widetilde{u}(t)\equiv 0\). This yields the uniqueness of solution to the problem (1.1)–(1.2). □

In order to obtain another result for uniqueness of the solutions, we make the following assumption:

(H3) There exists a constant \(\overline{L}_{f}>0\) such that

Theorem 5.5

Assume that (H3) holds, then the problem (1.1)–(1.2) has a unique solution\(u\in C_{1-\alpha }\), provided that

Proof

We consider an operator \(\mathcal{F}: C_{1-\alpha }\rightarrow C_{1-\alpha }\) defined by

Clearly, \(\mathcal{F}\) is well defined. According to (H3), we find

Then

this means that \(\mathcal{F}\) is a contraction, and by the Banach fixed point theorem there exists a unique solution \(u\in \mathcal{C}_{1-\alpha }\). □

Let ϵ̃ be a positive real number. We consider Eq. (1.1) with inequality

Definition 6.1

Equation (1.1) is Ulam–Hyers stable if there exists \(c > 0\) such that for each \(\widetilde{\epsilon } > 0\) and for each solution \(x(t)\) of the inequality (6.1) there exists a solution y of Eq. (1.1) with

Remark 6.2

A function \(x\in C_{1-\alpha }\) is a solution of the inequality (6.1) if and only if there exists a function \(g\in C_{1-\alpha }\) such that (i) \(|g(t)| \leq \widetilde{\epsilon }\); (ii) \({}^{c}{D_{1^{-}}^{\beta }}({} ^{L}{D_{0^{+}}^{\alpha }}+\lambda )x(t)=f(t, x(t))+g(t)\).

Let

where

Remark 6.3

Let \(x\in C_{1-\alpha }\) be a solution of the inequality (6.1) with \((I_{0^{+}}^{1-\alpha }x)(0)=u_{0}, \sum_{i=1}^{m} x( \xi _{i})=({} ^{\rho }{I_{0^{+}}^{\gamma }}x)(\eta )\). Then x is a solution of the inequality \(|x(t)-\tilde{x}(t)|\leq \frac{M_{3}\widetilde{\epsilon }}{\alpha \beta \gamma } \).

Indeed, by Remark 6.2, one can see

Then we have

where

It is easy to check that \(|x(t)-\tilde{x}(t)|\leq \frac{M_{3}\widetilde{\epsilon }}{\alpha \beta \gamma }\).

Theorem 6.4

Assume that (H3) is satisfied. If\(\overline{M}<1\), then Eq. (1.1) is Ulam–Hyers stable.

Proof

Let \(x \in C_{1-\alpha }\) be a solution of the inequality (6.1) with \((I_{0^{+}}^{1-\alpha }x)(0)=u_{0}, \sum_{i=1}^{m} x( \xi _{i})=({} ^{\rho }{I_{0^{+}}^{\gamma }}x)(\eta )\). y denotes the unique solution of the following problem:

It follows from (H3) that

Then we have

which implies \({\|x-y\|_{1-\alpha }\leq \frac{M_{3}\widetilde{\epsilon }}{\alpha \beta \gamma (1-\overline{M})}}\), furthermore

that is, Eq. (1.1) is Ulam–Hyers stable. □

In this section, we give two examples to illustrate our results.

Example 7.1

We consider the following boundary value problem:

Corresponding to (1.1)–(1.2), we have \(\alpha =\frac{1}{5}\), \(\beta =\frac{2}{5}\), \(\lambda =2\), \(\rho =\frac{7}{8}\), \(\gamma =2\), \(\xi _{i}=\frac{1}{2^{i}}(i=1,2,\ldots,100)\), \(\eta =\frac{1}{3}\) and

We define the space \(C_{\frac{4}{5}}=\{u\in C(J,\mathbb{R}): t^{\frac{4}{5}}u(t)\in C([0,1], \mathbb{R})\}\) with the norm \(\|u\|_{\frac{4}{5}}=\max_{t\in [0,1]}t^{\frac{4}{5}}|u(t)|\).

Obviously, \({|f(t,u(t))-f(t,\tilde{u}(t))|\leq 70|u(t)-\tilde{u}(t)|^{ \frac{1}{2}}}\) and \({|f(t,0)|=\frac{10}{\sqrt[5]{t}}|\sin 3t^{\frac{1}{4}}|} \leq 30\). By Theorem 5.3, the problem (7.1)–(7.2) has at least one solution.

Example 7.2

We consider the following boundary value problem for nonlinear fractional differential equation:

Set

For \(t\in J\), we have

Let \(\alpha =\frac{3}{5}\), \(\beta =\frac{1}{5}\), \(\lambda =3\), \(\rho =2\), \(\gamma =3\), \(\xi _{1}=\frac{1}{5}\), \(\xi _{2}=\frac{1}{4}\), \(\eta =\frac{1}{2}\), \(L'_{f}=\frac{1}{100}\), \(\widetilde{\sigma }=\frac{1}{2}\), \(\widetilde{M}_{f}=\frac{1}{10}\) and \(\widetilde{L}_{f}=\frac{1}{25}\). We define the space \(C_{\frac{2}{5}}=\{u\in C(J,\mathbb{R}): t^{\frac{2}{5}}u(t)\in C([0,1], \mathbb{R})\}\) with the norm \(\|u\|_{\frac{2}{5}}=\max_{t\in [0,1]}t^{\frac{2}{5}}|u(t)|\).

By direct computation, we have

Then

Thus by Theorem 5.4, the problem (7.3)–(7.4) has a unique solution.

Example 7.3

We consider the following boundary value problem for nonlinear fractional differential equation:

Set

For \(t\in J\), we have

Let \(\alpha =\frac{2}{3}\), \(\beta =\frac{1}{6}\), \(\lambda =2\), \(\rho =\frac{2}{3}\), \(\gamma =5\), \(\xi _{1}=\frac{1}{2}\), \(\eta =\frac{1}{10}\), \(\overline{L}_{f}=\frac{1}{10}\). We define the space \(C_{\frac{1}{3}}=\{u\in C(J,\mathbb{R}): t^{\frac{1}{3}}u(t)\in C([0,1], \mathbb{R})\}\) with the norm \(\|u\|_{\frac{1}{3}}=\max_{t\in [0,1]}t^{\frac{1}{3}}|u(t)|\).

By direct computation, we get

Then by Theorem 6.4, the problem (7.5)–(7.6) has a unique solution and Eq. (7.5) is Ulam–Hyers stable.

Acknowledgements

The authors thank the reviewers for their constructive comments, which led to the improvement of the original manuscript.

Availability of data and materials

Not applicable.

This work was supported partly by the NSF of China (11561077, 11971329) and the Reserve Talents of Young and Middle-Aged Academic and Technical Leaders of the Yunnan Province grant number 2017HB021.

Authors and Affiliations

1. School of Mathematics, Yunnan Normal University, Kunming, P.R. China

   Fang Li, Wenjing Yang & Huiwen Wang

Contributions

The authors contributed to each part of this study equally and read and approved the final version of the manuscript.

Corresponding author

Correspondence to Huiwen Wang.

Competing interests

The authors declare that they have no competing interests.

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