Existence of solutions for a system of singular sum fractional q-differential equations via quantum calculus

In this study, we discuss the existence of positive solutions for the system of m-singular sum fractional q-differential equations

with boundary conditions \(x_{i}(0) = x_{i}' (1) = 0\) and \(x_{i}^{(k)}(t) = 0\) whenever \(t=0\), here \(2\leq k \leq n-1\), where \(n= [\alpha_{i}]+ 1\), \(\alpha_{i} \geq2\), \(\gamma_{i} \in(0,1)\), \(D_{q}^{\alpha}\) is the Caputo fractional q-derivative of order α, here \(q \in(0,1)\), function \(g_{i}\) is of Carathéodory type, \(h_{i}\) satisfy the Lipschitz condition and \(g_{i} (t , x_{1}, \ldots, x_{2m})\) is singular at \(t=0\), for \(1 \leq i \leq m\). By means of Krasnoselskii’s fixed point theorem, the Arzelà-Ascoli theorem, Lebesgue dominated theorem and some norms, the existence of positive solutions is obtained. Also, we give an example to illustrate the primary effects.

Fractional calculus and q-calculus belong to the significant branches in mathematical analysis. In 1910, Jackson introduced the subject of q-difference equations [1]. Later, many researchers studied q-difference equations [2–12]. On the other hand, there appeared recently much work on q-differential equations by using different views and fractional derivatives; young researchers could use the main idea in their work (see, for example, [13–30]).

In 2010, the singular Dirichlet problem \(D^{\alpha} x(t) + g(t, x(t), D^{\gamma} x(t) )=0\) under conditions \(x(0) = x(1) = 0\) was investigated by Agarwal et al., where α, γ belong to \((1,2)\), \((0, \alpha- 1 )\), respectively, the function g is of Carathéodory type on \([0,1] \times(0 , \infty) \times\mathbb{R}\) and \(D^{\alpha}\) is the Riemann–Liouville fractional derivative [23]. In 2012, the fractional differential equation \({}^{c}D^{\alpha} y(t) + w(t,y(t))=0\), under boundary conditions \(y(0)=y''(0)=0\) and \(y(1)= \lambda\int_{0}^{1} y(s) \,ds\), was investigated, where \(t, \alpha, \lambda \in(0,1), (2, 3), (0, 2)\), respectively, and the function \(w: J \times[0,\infty) \rightarrow [0,\infty)\) is continuous [24]. Also, in the same year, Ahmad et al., discussed the existence and uniqueness of solutions for the fractional q-difference equations \({}^{c}D_{q}^{\alpha}u(t)= T ( t, u(t) ) \), \(\alpha_{1} u(0) - \beta_{1} D_{q} u(0) = \gamma_{1} u(\eta_{1})\), and \(\alpha_{2} u(1) - \beta_{2} D_{q} u(1) = \gamma_{2} u(\eta_{2})\), for \(t \in I\), where \(\alpha\in(1, 2]\), \(\alpha_{i}, \beta _{i}, \gamma_{i}, \eta_{i} \in\mathbb{R}\), for \(i=1,2\) and \(T \in C([0,1] \times\mathbb{R}, \mathbb{R})\) [6]. In 2013, Zhao et al. reviewed the q-integral problem \((D_{q}^{\alpha}u)(t) + f(t, u(t) )=0\), with conditions \(u(1)\), \(u(0)\) being equal to \(\mu I_{q}^{\beta}u(\eta) \), 0, respectively, for almost all \(t \in(0,1)\), where \(q \in(0,1)\), and α, β, η belong to \((1, 2]\), \((0, 2]\), \((0,1)\), respectively, μ is a positive real number, \(D_{q}^{\alpha}\) is the q-derivative of Riemann–Liouville and we have the real-valued continuous map u defined on \(I \times[0, \infty) \) [10].

In 2014, the singular fractional problem \({}^{c}D_{0^{+}}^{\alpha} x(t)+ f(t , x(t), {}^{c}D_{0^{+}}^{\sigma} x(t))=0\) with boundary conditions \(x(0)=x'(0)=0\) and \(x'(1)= {}^{c}D_{0^{+}}^{\sigma} x(1)\) investigated, where t, α, σ belong to \((0,1)\), \((2, 3)\), \((0, 1)\), respectively, \(f: (0,1] \times\mathbb{R}^{2} \to\mathbb{R} \) is continuous with \(f(t,x,y)\) may be singular at \(t=0\) and \({}^{c}D_{0^{+}}^{\alpha}\) is the Caputo derivative [31]. In 2017, Aydogan et al. and Shabibi et al. studied sum-type singular fractional integro-differential equation with k-point boundary conditions together some properties and sum fractional differential system with some conditions, respectively [21, 22]. Also, in the same year, Zhou et al., provided existence criteria for the solutions of p-Laplacian fractional Langevin differential equations with anti-periodic boundary conditions:

and

for \(t \in[0,1]\), where \(0 < \alpha, \beta\leq1\), λ is larger than or equal to zero, \(1 < \alpha+ \beta<2\), \(q \in(0,1)\), and \(\phi(p) (s) = |s|^{p-2} s\), with \(p \in(1, 2]\) [15]. In 2019, Samei et al., investigated existence of solutions for equations and inclusions of multi-term fractional q-integro-differential equations with non-separated and initial boundary conditions [9].

In this article, motivated by main idea of this work and by these achievements, we are working to address the positive solutions for system of singular sum fractional q-differential equations

under some conditions \(x_{i}(0) = 0\), \(x_{i}' (1) = 0\) and \(\frac{ d^{k} x_{i}(t)}{d t^{k}} |_{t=0} = 0\), for \(i \in N_{m}\) and \(k \in N_{n-1} \setminus\{1\}\), where \(\alpha_{i} \geq2\), \([\alpha_{i}]= n - 1\), \(\gamma_{i} \in J=(0,1)\), \(D_{q}^{\alpha}\) is the Caputo fractional q-derivative of order α, the function \(g_{i}\) is of Carathéodory type, \(h_{i}\) satisfy Lipschitz condition and \(g_{i} (t , x_{1}, \ldots, x_{2m})\) is singular at \(t=0\) for \(i \in N_{m} \), where \(N_{\kappa}= \{1,2, \dots, \kappa\}\).

The rest of the paper is arranged as follows. In Sect. 2, we recall some preliminary concepts and fundamental results of q-calculus. Section 3 is devoted to the main results, while examples illustrating the obtained results and algorithm for the problems are presented in Sect. 4.

First, we point out some of the materials on the fractional q-calculus and fundamental results of it which are needed in the next sections (for more information, refer to [1, 32, 33]). Then, some well-known theorems as regards the fixed point theorem and definitions are presented.

The proposed method for calculated \((a-b)_{q}^{(\alpha)}\)

Full size image

The proposed method for calculated \(\varGamma_{q}(x)\)

Full size image

The proposed method for calculated \((D_{q} f)(x)\)

Full size image

The proposed method for calculated \((I_{q}^{\alpha}f)(x)\)

Full size image

The proposed method for calculated \(\int_{a}^{b} f(r) \,d_{q} r\)

Full size image

Assume that \(q \in(0,1)\) and \(a \in\mathbb{R}\). Define \([a]_{q}=\frac {1-q^{a}}{1-q}\) [1]. The power function \((x-y)_{q}^{n}\) with \(n \in\mathbb{N}_{0} \) is \((x-y)_{q}^{(n)}= \prod_{k=0}^{n-1} (x - yq^{k})\) and \((x-y)_{q}^{(0)}=1\) where x, y are real numbers and \(\mathbb{N}_{0} := \{ 0\} \cup\mathbb{N}\) [32]. Also, for real number α and \(a \neq0\), we have \((x-y)_{q}^{(\alpha )}= x^{\alpha}\prod_{k=0}^{\infty}(x-yq^{k}) / (x - yq^{\alpha+ k})\). If \(y=0\), then it is clear that \(x^{(\alpha)}= x^{\alpha}\) (Algorithm 1). The q-Gamma function is given by \(\varGamma_{q}(z) = (1-q)^{(z-1)} / (1-q)^{z -1}\), where \(z \in\mathbb{R} \setminus\{0, -1, -2, \ldots\}\) [1]. Note that \(\varGamma_{q} (z+1) = [z]_{q} \varGamma_{q} (z)\). The value of the q-Gamma function, \(\varGamma_{q}(z)\), holds for input values q and z with counting the number of sentences n in summation by simplifying analysis. For this design, we prepare a pseudo-code description of the technique for estimating the q-Gamma function of order n which we show in Algorithm 2. The q-derivative of the function f is defined by \((D_{q} f)(x) = \frac {f(x) - f(qx)}{(1- q)x}\) and \((D_{q} f)(0) = \lim_{x \to0} (D_{q} f)(x)\), which is shown in Algorithm 3 [2]. Also, the higher order q-derivative of a function f is defined by \((D_{q}^{n} f)(x) = D_{q}(D_{q}^{n-1} f)(x)\) for all \(n \geq1\), where \((D_{q}^{0} f)(x) = f(x)\) [2]. The operator

for \(0 \leq x \leq b\), is called the q-integral of a function f, whenever the series is absolutely converges [2]. If a in \([0, b]\), then

whenever the series exists. The operator \(I_{q}^{n}\) is given by \((I_{q}^{0} f)(x) = f(x) \) and

for \(n \geq1\) [2]. It has been proved that \((D_{q} (I_{q} f))(x) = f(x) \) and \((I_{q} (D_{q} f))(x) = f(x) - f(0)\) whenever f is continuous at \(x =0\) [2]. The fractional Riemann–Liouville type q-integral of the function f on \([0,1]\), for \(\alpha\geq0\), is given by \((I_{q}^{0} f)(t) = f(t) \) and

for \(t \in J\) and \(\alpha>0\) [4, 7]. Also, the fractional Caputo type q-derivative of the function f is given by

for \(t \in[0,1]\) and \(\alpha>0\) [4, 7]. It has been proved that \(( I_{q}^{\beta} (I_{q}^{\alpha} f)) (x) = ( I_{q}^{\alpha+ \beta} f) (x)\) and \((D_{q}^{\alpha} (I_{q}^{\alpha} f) ) (x) = f(x)\), where \(\alpha, \beta\geq0\) [7]. By using Algorithm 2, we can calculate \((I_{q}^{\alpha}f)(x)\) which is shown in Algorithm 4. One can find more details of fractional differential and q-differential equations in [34–37].

Now, we present some necessary notions. Throughout this article, we denote \(L^{1}(0,1)\), \(L^{1}[0,1]\), \(C_{\mathbb{R}}(0,1)\), \(C_{\mathbb {R}}[0,1]\), \(C_{\mathbb{R}}^{1}[0,1]\) by \(\mathcal{L}\), \(\overline {\mathcal{L}}\), \(\mathcal{A}\), \(\overline{\mathcal{A}}\), \(\overline {\mathcal{B}}\), respectively. We say that a map \(\theta: \overline{J} \times\mathcal{S} \to\mathbb{R}^{n}\) is of Carathéodory type whenever the function \(t \mapsto\theta( t, r_{1}, \dots, r_{n})\) is measurable for all \((r_{1},\dots, r_{n}) \in\mathcal{S}\) and \((r_{1}, \dots, r_{n})\mapsto\theta(t, r_{1}, \dots, r_{n})\) is continuous for \(t \in \overline{J}\) and for each compact \(C \subseteq\mathcal{S}\) there exists \(\psi_{C} \in\overline{\mathcal{L}}\) such that \(|\theta( t, r_{1}, \dots, r_{n}) |\leq\psi_{C} (t)\) for each \(t \in\overline{J}\) and \((r_{1}, \dots, e_{n}) \in C\), here \(\mathcal{S} = (0,\infty)^{2m}\). At present, we consider four norms which will be used in the sequel: \(\| x \| := \sup\{ |x(t)|: t \in\overline{J}\}\), \(\| x \|_{1} := \int_{0}^{1} |x(t)|\, dt\), \(\| (x_{1}, x_{2}, \dots, x_{n}) \|_{*} := \max\{ \| x_{i} \| : i\in N_{n}\}\) and

The following lemmas can be found in [34, 36–38].

Lemma 1

If \(x \in\overline{\mathcal{A}} \cap\overline{\mathcal{L}}\)with \(D_{q}^{\alpha} x\in\mathcal{A} \cap\mathcal{L}\), then \(I_{q}^{\alpha} D_{q}^{\alpha} x(t) =x(t) + \sum_{i=1}^{n} c_{i} t^{\alpha- i}\), wherenis the smallest integer greater than or equal toαand \(c_{i}\)is some real number.

Lemma 2

Assume that a nonempty subsetCof a Banach space \(\mathcal{X}\)be a closed, convex. Then, there exists \(c \in C\)such that \(c=\mathcal{O}_{1} (c) + \mathcal{O}_{2} (c)\)whenever the operators \(\mathcal{O}_{1}\)and \(\mathcal{O}_{2}\)are compact and continuous, or a contraction, respectively.

Lemma 3

The unique solution for \(D_{q}^{\alpha}x(t) + v(t) = 0\)under conditions \(x'(1)= x(0) =x''(0) = \cdots= x^{n-1}(0) =0\), here \(v \in\overline {\mathcal{L}}\), \(\alpha\in[2, \infty)\)and \(n = [\alpha] +1\), is \(x(t)= \int^{1}_{0} G_{\alpha}(t,qs) v(s) \,d_{q}s\), where

whenever \(t \leq s\)and

whenever \(s \leq t\), for all \(t, s \in\overline{J}\).

Proof

At first, by applying Lemma 1 and the boundary conditions, we conclude that \(x(t)= -I_{q}^{\alpha}v(t) + c_{1} t\) and so \(x'(1) = -I_{q}^{\alpha-1} v(1) + c_{1}\). Since \(x'(1) = 0\), \(c_{1}= I_{q}^{\alpha-1} v(1)\). Thus, \(x(t) = - I_{q}^{ \alpha} v(t) + tI_{q}^{\alpha-1} v(1)\). Hence, we obtain

where

for each \(t, s \in\overline{J}\). □

Remark 1

Consider a q-Green function as in (3). It can be seen that \(G_{\alpha} (t,qs) >0 \) if \(t \leq s\) for each \(t, s \in J\). Also, \(G_{\alpha} (t,qs) >0\) whenever \(s < t\) if and only if \((t -qs)^{(\alpha-1)} < t (\alpha-1) ( t -qs)^{(\alpha-2)}\) for all \(t, s \in J\). In addition

and \(\frac{\partial}{\partial t} G_{\alpha}(t,qs) > 0\) for \(t,s \in J\). Moreover, \(G _{\alpha}\), \(\frac{ \partial}{ \partial t} G_{\alpha} \in C_{\mathbb{R}}(\overline{J} \times\overline{J})\), \(\frac{ \partial}{ \partial t} G_{\alpha}(t,qs) \leq\frac{1}{ \varGamma _{q}( \alpha-1)}\) and \(\int^{1}_{0} \frac{ \partial}{ \partial t} G_{\alpha}(t,s) \geq\frac{1-t^{\alpha-1}}{\varGamma( \alpha)}\), for almost all \(t, s \in\overline{J}\).

Remark 2

Let \(u \in C_{\mathbb{R}}^{1} (\overline{J})\) and \(\gamma\in J\). Since

for all \(t \in\overline{J}\),

and so \(\varGamma_{q}( 2 -\gamma) |D_{q}^{\gamma} u| \leq \Vert u' \Vert \) and \(D_{q}^{\gamma} u \in C_{\mathbb{R}}(\overline{J})\).

Now, we consider the following assumptions for the problem (1):

1. (A1)

   The maps \(g_{i}\) are Carathéodory functions on \(\overline {J} \times\mathcal{S}\) and there exist positive constants \(\ell_{i}\) such that \(g_{i} ( t, u_{1}, \dots, u_{2m} ) \geq\ell_{i}\) for each \(t \in\overline{J}\) and all \(( u_{1}, \dots, u_{2m}) \in\mathcal {S}\) where \(i \in N_{m}\).

2. (A2)

   The maps \(h_{i}\) are nonnegative and

   $$ \bigl\vert h_{i} ( t, u_{1}, \dots, u_{2m} ) - h_{i} (t, v_{1}, \dots, v_{2m} ) \bigr\vert \leq\sum_{k=1}^{2m} {}_{i}M_{k} \vert u_{k} - v_{k} \vert , $$

   (6)

   for each t belonging to J̅ and for almost all \((u_{1}, \dots, u_{2m}), (v_{1}, \dots, v_{2m}) \in\mathcal{S}\), where \({}_{i}M_{j}\) in \([0,\infty)\), for \(i \in N_{m}\) and \(j \in N_{2m}\), are constants such that

   $$ \sum_{k=1}^{m} \biggl( {}_{i}M_{k} + \frac{ {}_{i}M_{m + k} }{ \varGamma _{q}(2 - \gamma_{i})} \biggr) < \varGamma_{q}( \alpha_{i} - 1). $$

   (7)
3. (A3)

   There exist some maps \(\mu_{1}, \dots, \mu_{m} \in\overline {\mathcal{L}}\), some nonincreasing maps \(r_{1}, \dots, r_{m} \in C_{\mathbb {R}}(\mathcal{S})\) with

   $$\int_{0}^{1} r_{i} \biggl( L_{1} t^{\alpha_{1}}, \dots, L_{m} t^{ \alpha _{m}}, \frac{ L_{1} (1 - \gamma_{1})}{ 2 } t^{ 1 - \gamma_{1}}, \dots, \frac{ L_{m} (1- \gamma_{m})}{2} t^{1 - \gamma_{m}} \biggr) \, dt < \infty $$

   and some functions \(w_{1}, \dots, w_{m} \in C_{\mathbb{R}}( \mathcal{S} )\) such that \(w_{i}\) is nondecreasing in all components, \(\lim_{x \to \infty} \frac{ w_{i} (x, \dots, x)}{x} = 0\) and

   $$ \begin{aligned}[b] &g_{i} (t, u_{1}, \dots, u_{2m}) + h_{i} (t, u_{1}, \dots, u_{2m} ) \\ &\quad \leq r_{i}( u_{1}, \dots, u_{2m}) + \mu_{i} (t) w_{i} (u_{1}, \dots, u_{2m}), \end{aligned} $$

   (8)

   for almost all \(t \in\overline{J}\) and all \(( u_{1}, \dots, u_{2m}) \in \mathcal{S}\) where \(L_{i} \varGamma_{q}(\alpha_{i} + 1) = \ell_{i}(\alpha _{i} - 1)\) for all \(i \in N_{m}\).

Now, we prove the following lemma.

Lemma 4

Suppose that \(\mathcal{P}\)is the set of all \(( u_{1}, \dots, u_{m} ) \)belonging to \(\overline{\mathcal{B}}^{m}\)such that \(u_{i}(t) \)and \(u'_{i}(t) \)are larger than or equal to zero for \(t \in\overline {J}\)and \(i\in\{0\} \cup N_{m}\). Also, for each natural numbernand \(i \in N_{m}\), we define the maps

and

for all \(( u_{1} , \dots, u_{m})\in\mathcal{P}\). Then the self-mapHdefine on \(\mathcal{P}\)is a contraction.

Proof

First, by simple review, we can check that \(H_{i} ( u_{1} , \dots, h_{m}) (t) \geq0\) and

for all \(t \in\overline{J}\), \((u_{1}, \dots, u_{m}) \in\mathcal{P}\) and \(i \in \{0\} \cup N_{m}\). On the other hand,

By using Remark 2, we can conclude that

for \(i \in N_{m} \cup\{0\} \). Hence,

In a similar way, we obtain

Thus, we have

By assumption (A2) and inequality (7), we conclude that H is a contraction mapping. □

At present, for \(i \in N_{m}\) and \(n \in\mathbb{N}\), we take

where \(\chi_{n}(x)=x\) whenever \(x\geq\frac{1}{n}\) and \(\chi_{n} (x) = x\) whenever \(x < \frac{1}{n}\). By simple review, we can check that

\(F_{i,n} (t, u_{1} , \dots, u_{2m} ) \geq\ell_{i}\) and

for all \((u_{1}, \dots, u_{n}) \in\mathcal{S}\), \(i \in N_{m}\) and each \(t \in\overline{J}\).

First, we investigate the system of regular fractional q-differential equations

with the same boundary conditions as in (1).

Lemma 5

Suppose that \(\mathcal{P}\)is the set which is defined in Lemma 4and \(i\in\{0\} \cup N_{m} \). Also, let us, for each natural numbernand \(i \in N_{m}\), define the maps

and

for all \(( u_{1} , \dots, u_{m})\in\mathcal{P}\). Then \(\varOmega_{n}\)is a completely continuous operator on \(\mathcal{P}\)for each natural numbern.

Proof

Assume that \(( u_{1} , \dots, u_{m}) \in\mathcal{P}\). We choose a positive constant \(\ell_{i}\) such that

for almost all \(t \in\overline{J}\). Since \(G_{\alpha_{i}}\) and \(\frac {\partial}{\partial t} G_{\alpha_{i}}\) are nonnegative and continuous on \(\overline{J}^{2}\) for each \(i \in N_{m}\), we conclude that \(T_{i,n} ( u_{1}, \dots, u_{m} )(t) \) and \(( T_{i,n} ( u_{1} , \dots, u_{m} ) )'(t)\) larger than or equal to zero, for all \(t\in\overline{J}\) and \(i \in N_{m}\). Indeed, \(\varOmega_{n}\) maps P into P. Consider a convergent sequence \(\{ ( u_{1,k} , \dots, u_{m,k}) \} \subseteq\mathcal{P}\) with \(\lim_{k \to\infty} ( u_{1,k} , \dots, u_{m,k}) = (u_{1} , \ldots, u_{m})\). In this case, we get \(\lim_{k \to \infty} u_{i,k} = u_{i}\) and \(\lim_{k \to\infty} u'_{i,k} = u'_{i}\) uniformly on J̅ (\(i \in N_{m}\)). But

for each t in J̅ and \(i \in N_{m}\). Hence, \(\lim_{k \to \infty} D^{\mu_{i}} x_{i,k}(t) = D^{\mu_{i}} x_{i}(t)\) uniformly on J̅. Hence,

Since \(F_{i,n} \in C ( \overline{J} \times\mathbb{R}^{2m} )\), the sequence \(\{(u_{1,k} , \dots, u_{m,k}) \} \subseteq \overline{\mathcal{B}}^{m}\) is bounded, there exists a map \(\mu_{i} \in \overline{\mathcal{L}}\) such that

for almost all \(t \in\overline{J}\), \(i \in N_{m}\) and \(k \in\mathbb {N}\). By using the dominated convergence theorem of Lebesgue, we conclude that

and

Hence,

uniformly on J̅ for \(j=0,1\). Thus,

and so \(\varOmega_{n}\) is continuous. Let \(\{ ( u_{1,k} , \dots, u_{m,k}) \} \subseteq\mathcal{P}\) be a bounded sequence. We choose a positive number M such that \(\Vert u_{i,k} \Vert \) and \(\Vert u'_{i,k} \Vert \) are smaller than or equal to M for all \(i \in N_{m}\) and \(k \geq1\). Since \(\Vert D_{q}^{\gamma_{i}} u_{i,k} \Vert \varGamma_{q}( 2 - \gamma_{i}) \leq1\) for each \(i \in N_{m}\), there exists a map \(\mu_{i} \in\overline{\mathcal {L}}\) such that inequality (14) holds for almost all \(t \in \overline{J}\), \(i \in N_{m}\) and \(k \geq1\). On the other hand,

and

for all \(i \in N_{m}\). Hence,

Indeed, \(\{ \varOmega_{n} ( u_{1,k} , \dots, u_{m,k}) \}\) is bounded in \(\overline{\mathcal{B}}^{m}\). Assume that \(t_{1}, t_{2} \in\overline {J}\) such that \(t_{1} \leq t_{2} \) and \(i \in N_{m}\). Then, we have

Since the function \(|t - qs|^{(\alpha_{i} -1)}\) is uniformly continuous on \(\overline{J}^{2} \), there exists \(\delta> 0\) such that \(( t_{2} - qs)^{(\alpha_{i} -1)} - ( t_{1} - qs)^{(\alpha_{i} -1)} < \varepsilon\) for all \(t_{1}, t_{2} \in\overline{J}\) with \(t_{1} \leq t_{2}\), \(t_{2} - t_{1} < \delta\) and \(s \in[0, t_{1}]\), where \(\varepsilon> 0\) be given. Take \(t_{2} - t_{1} < \min\{ \delta, \varepsilon\}\), then we have

Thus,

This implies that \(\{ \varOmega'_{n} ( u_{1,k}, \dots, u_{m,k}) \}\) is equi-continuous on J̅. At present, by using the Arzelà-Ascoli theorem, \(\{ \varOmega_{n} ( u_{1,k} , \dots, u_{m,k}) \}\) is relatively compact. Therefore \(\varOmega_{n}\) is completely continuous. □

Now, we are ready to provide our main results about the problem (1).

Theorem 6

The problem (11) under boundary conditions in (1) has a solution \(( u_{1,n} , \dots, u_{m,n}) \)belongs to \(\mathcal{P}\)such that \(u_{i,n}(t) \varGamma (\alpha_{i} + 1) \geq\ell_{i} t^{\alpha_{i}} (\alpha_{i} -1)\), for all \(t \in\overline{J}\)and \(i \in N_{m}\), whenever assumptions (A1) and (A2) hold.

Proof

The mapping \(H: P \to P\) is a contraction and the operator \(\varOmega_{n} : P \to P\) is completely continuous, by employing Lemma 4 and Lemma 5, respectively. Now, by applying Lemma 2, there exists \(( u_{1,n} , \dots, u_{m,n}) \in\mathcal{P}\) such that \(( u_{1,n} , \dots, u_{m,n}) = \varOmega_{n} ( u_{1,n} , \dots , u_{m,n}) + H ( u_{1,n} , \dots, u_{m,n})\). Therefore, \(u_{i,n}= T_{i,n} ( u_{1,n} , \dots, u_{m,n}) + H_{i} ( u_{1,n} , \dots, u_{m,n})\) for all \(i \in N_{m}\). Hence,

for all \(i \in N_{m}\). By applying the hypothesis, we obtain \(u_{i,n}(t) \varGamma(\alpha_{i} + 1) \geq\ell_{i} t^{\alpha_{i}} (\alpha_{i} -1)\) for all \(t \in\overline{J}\) and \(i \in N_{m} \). By simple review, we can see that the element \(( u_{1,n} , \dots, u_{m,n}) \in\mathcal{P}\) is a solution of the problem (11) under the boundary conditions in (1). □

Lemma 7

Let the element \((u_{1,n} , \dots, u_{m,n}) \)be a solution for the problem (11) under the boundary conditions in (1). Then \(\{ ( u_{1,n} , \dots, u_{m,n} ) \}_{n\geq1}\)is relatively compact in \(\mathcal{P}\)whenever assumptions (A1), (A2) and (A3) hold.

Proof

As we found in Theorem 6,

for all \(n \in\mathbb{N}\), \(t \in\overline{J}\) and \(i \in N_{m}\). Hence,

for \(t \in\overline{J}\) and so,

Thus,

for \(t \in\overline{J}\). Since \(\varGamma_{q}(3- \gamma_{i}) \leq2\), we have \(2 \varGamma_{q}(\alpha_{i}) D_{q}^{\gamma_{i}} u_{i,n} (t) \geq \ell _{i} t^{1-\gamma_{i}}(1 - \gamma_{i})\). Now, put

Therefore, \(u_{i,n} (t) \geq L_{i} t^{\alpha_{i}}\) and \(2 D_{q}^{\gamma _{i}} u_{i,n} (t) \geq L_{i} (1-\gamma_{i}) t^{1-\gamma_{i}}\) for all \(n \geq 1\), \(t \in\overline{J}\) and \(i \in N_{m}\). Indeed,

for \(n \in\mathbb{N}\), \(t \in\overline{J}\) and \(i \in N_{m}\). Hence, we conclude that

for all \(t \in\overline{J}\), \(n\geq1\) and \(i \in N_{m}\). Also, for all \(i \in N_{m}\), we obtain

Assume that \(\lambda_{n} = \Vert ( u_{1,n} , \dots, u_{m,n} ) \Vert _{**}\). Then, for all i and n, we have \(\| u_{i,n} \| \) and \(\Vert u'_{i,n} \Vert \) smaller than or equal to \(\lambda_{n}\). Thus, \(\varGamma_{q}(2 - \gamma _{i}) |D_{q}^{\gamma_{i}} u_{i,n}(t)| \leq \lambda_{n} \) for each \(n \in\mathbb{N}\), \(t \in\overline{J}\) and \(i \in N_{m}\). Hence

and \(0 \leq u_{i,n}(t) = \int^{t}_{0} u'_{i,n}(s) \,ds \) for \(n \in\mathbb {N}\), \(t \in\overline{J}\) and \(i \in N_{m}\). By a similar method, we get

for all i. Since \(\lim_{x \to\infty} \frac{w_{i} (x, \dots, x)}{x} = 0\) for all \(i \in N_{m}\), there exists \(M_{i} > 0\) such that

for all \(\nu_{i}> M_{i}\). We take \(M = \max\{M_{1}, \dots, M_{m}\}\). Then we have

for all \(\nu> M\). Thus,

which implies \(\{ \Vert ( u_{1,n} , \dots, u_{m,n}) \Vert _{**} \} \) is bounded in \(\overline{ \mathcal{B}}_{m}\). Now, take

and

for all i and each \(t\in\overline{J}\). Then, we have \(\varLambda_{i} = \int^{1}_{0} U_{i} (t) \,dt\) and

If \(t_{1} , t_{2} \in\overline{J}\) such that \(t_{1} \leq t_{2}\), then we obtain

Let \(\varepsilon_{i} > 0\) be given. Choose \(\delta( \varepsilon_{i} ) > 0\) such that

for all \(0 \leq t_{1} < t_{2} \leq1\) with \(t_{2} - t_{1} < \delta( \varepsilon_{i} )\) and \(s \in(0, t]\). Take

then \(\varGamma_{q}( \alpha_{i} -1) \vert u'_{i,n} ( t_{2}) - u'_{i,n} (t_{1} ) \vert \leq 3 \varepsilon_{i} ( \varLambda_{i} + C_{i} \Vert \mu _{i} \Vert _{1} )\), for all \(i \in N_{m}\). Hence, \(\{( u_{1,n} , \dots, u_{m,n})' \}\) is equi-continuous. Indeed, \(\{(u_{1,n} , \dots, u_{m,n}) \}_{n \geq1} \subseteq\overline{\mathcal{B}}^{m}\) is relatively compact. □

Theorem 8

The system (1) has a solution \(( u_{1} , \ldots, u_{m}) \in \mathcal{P}\)such that \(2 D_{q}^{ \gamma_{i}} u_{i} (t) \geq L_{i} (1- \gamma_{i}) t^{1 - \gamma_{i}}\)and \(u_{i} (t) \geq L_{i} t^{\alpha _{i}}\)for all \(t \in\overline{J}\)and \(i \in N_{m}\)whenever the assumptions (A1), (A2) and (A3) hold.

Proof

As we found in Theorem 6, for each natural number n the system (11) under the boundary conditions in (1) has a solution \(( u_{1,n} , \dots, u_{m,n} ) \) in \(\mathcal{P}\). By applying Lemma 7, we have \(\{ ( u_{1,n}, \dots, u_{m,n}) \}_{n\geq1}\) is relatively compact in \(\overline{\mathcal{B}}^{m}\). Also, by employing the Arzelá–Ascoli theorem, \(( u_{1} , \dots, u_{m})\) exists such that \(\lim_{n \to\infty} ( u_{1,n} , \dots, u_{m,n}) = ( u_{1} , \dots, u_{m})\). It is obvious that \(( u_{1} , \dots, u_{m})\) satisfies the boundary conditions of the problem (1), \(D_{q}^{\gamma_{i}} u_{i,n} \to D_{q}^{\gamma_{i}} u_{i}\) and

for each t belonging to J̅ and \(i \in N_{m}\). Thus \(( u_{1} , \dots, u_{m}) \in\mathcal{P}\). At present, suppose that \(K = \sup_{n\geq1} \Vert ( u_{1,n} , \dots, u_{m,n}) \Vert _{**}\). Then we have \(\Vert D_{q}^{\gamma_{i}} u_{i,n} \Vert \leq\frac{K}{ \varGamma _{q}(2 - \gamma_{i})}\) for all n and \(i \in N_{m}\). Hence,

for almost all \((t,qs) \in\overline{J}^{2} \), \(n \geq1\) and \(i \in N_{m}\). At present, the dominated theorem of Lebesgue implies that

for all \(i \in N_{m}\) and \(t \in\overline{J}\). This completes the proof. □

In this part, we give complete computational techniques for illustrating of the problem (1), in Theorems 8, such that it covers all the problems, and present numerical examples which solve the problems perfectly. Foremost, we present a simplified analysis that can be executed to calculate the value of q-Gamma function, \(\varGamma_{q} (x)\), for input values q and x by counting the number of sentences n in summation. To this aim, we consider a pseudo-code description of the method for the calculated q-Gamma function of order n in Algorithm 2 (for more details, see the following link: https://en.wikipedia.org/wiki/Q-gamma_function). Table 1 shows that when q is constant, the q-Gamma function is an increasing function. Also, for smaller values of x, an approximate result is obtained with smaller values of n. It is shown by underlined rows. Table 2 shows that the q-Gamma function for values q close to 1 is obtained with higher values of n in comparison with other columns. They have been underlined in line 8 of the first column, line 17 of the second column and line 29 of third columns of Table 2. Also, Table 3 is the same as Table 2, but x values increase in 3. Similarly, the q-Gamma function for values q near to one is obtained with more values of n in comparison with other columns. Furthermore, we provide Algorithm 3, which calculates \((D_{q}^{\alpha}f) (x)\).

Here, we provide an example to illustrate the results of Theorem 8.

Example 1

Consider the system as (1) with \(m= 2\):

under boundary conditions \(u_{1}(0) = u_{2}(0)= 0\), \(u'_{1}(1) = u'_{2}(1)= 0\) and \(u''_{1}(0) = u''_{2}(0)= 0\), where \(c_{i}, d_{i}\) are positive constants, for \(i=1,2,3,4\). Note that \(\mathcal{S}=(0, \infty)^{4}\). We take the functions

\(\lambda_{1}(t) = \frac{1}{ \sqrt[3]{t^{2}}}\) and \(\lambda_{2}(t)= \frac {1}{\sqrt{t}}\). Put \(m= 2\), \(\alpha_{1} = \frac{5}{2}\), \(\alpha_{2} = \frac{7}{3}\), \(\gamma_{1} = \frac{1}{2}\), \(\gamma_{2} = \frac{1}{3}\),

\(\ell_{1} = 2\) and \(\ell_{2}= 1\). By simple review, we can see that \(g_{1}\) and \(g_{2}\) are Carathéodory functions, \(g_{1} (t, u_{1}, u_{2}, u_{3}, u_{4}) \geq2\), \(g_{2}(t, u_{1}, u_{2}, u_{3}, u_{4}) \geq1\) for all \(( u_{1}, u_{2}, u_{3}, u_{4}) \in\mathcal{S}\) and each \(t \in \overline{J}\), \(h_{1}\) and \(h_{2}\) are nonnegative and \(h_{1}\), \(h_{2}\) satisfy inequality (6):

for \((u_{1}, u_{2}, u_{3}, u_{4}), (v_{1}, v_{2}, v_{3}, v_{4}) \in(0,\infty)^{4}\) and \(t \in\overline{J}\). Also, by putting values in the problem in (7), we have

Tables 4 and 5 show the values of inequalities (16) and (17), respectively. On the other hand, the maps \(r_{1}\) and \(r_{2}\) are nonincreasing with respect to all components. If

then

Also, the functions \(w_{1}\) and \(w_{2}\) are nondecreasing with respect to all components and

Therefore, Theorem 8 implies that the problem (15) has a positive solution.

Not applicable.

Not applicable.

Authors and Affiliations

1. Department of Mathematics, Bu-Ali Sina University, Hamedan, Iran

   Mohammad Esmael Samei

Contributions

The author was the only one to contribute to this manuscript and read and approved the final manuscript.

Corresponding author

Correspondence to Mohammad Esmael Samei.

Ethics approval and consent to participate

Not applicable.

Competing interests

The author declares to have no competing interests.

Consent for publication

Not applicable.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.

Reprints and permissions