Faten Toumi
College of Business Administration, King Faisal University, Ahsaa, Saudi Arabia.
DOI: 10.4236/am.2023.143011   PDF    HTML   XML   113 Downloads   568 Views   Citations

Abstract

We aim, in this work, to demonstrate the existence of minimal and maximal coupled quasi-solutions for nonlinear Caputo fractional differential systems with order q ∈ (1,2). Our approach is based on mixed monotone iterative techniques developed under the concept of lower and upper quasi-solutions. Our results extend those obtained for ordinary differential equations and fractional ones.

Keywords

Mixed Quasi-Monotone Property, Coupled Lower and Upper Solutions, Mon-otone Method, Nonlinear Fractional Differential System

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1. Introduction

Fractional differential equations and systems are appearing in a variety of scientific and engineering branches being mathematical modelling in many fields, namely, in Physics, electromagnetic, acoustic, viscoelasticity, electrochemistry, economics, signal and image processing, control theory, etc. For details, one can see [1] - [8]. Many works treated the problems concerning fractional differential equations or systems by using several methods. Essentially, the authors used the techniques of nonlinear analysis to study these problems. We quote the power series method [9], the compositional method [9], the variational Lyapunov method [10], the Adomian decomposition method [11], the generalized monotone method [12], by the means of fixed point theorems [13]. Recently, the method combining the method of lower and upper solutions, and the monotone iterative techniques were frequently, served for the study of both fractional differential equations or systems involving Caputo or Riemann-Liouville Derivatives, especially for the order q in $\left(\mathrm{0,1}\right)$ , we refer readers to the cited works as examples [14] - [20]. This restriction is due to that the comparison result has been established only for the order $0<q<1$ until the works of Shi [21] and Al-Refai [22] which treated the case $1<q<2$ . In [23], Ramirez and Vatsala were interested in the differential equation involving the Riemann-Liouville fractional derivative

$D^{q}u\left(t\right)=f\left(t\mathrm{,}u\left(t\right)\right)\text{in}\left(a\mathrm{,}b\right)$

with periodic boundary conditions

$u\left(a\right)={\left(t-b\right)}^{1-q}{u\left(t\right)|}_{t=b}$

where $q\in \left(\mathrm{0,1}\right]$ , $f\in \mathcal{C}\left(\left[a\mathrm{,}b\right]\times ℝ\mathrm{,}ℝ\right)$ . The authors showed the existence of minimal and maximal solutions. Their method was grounded in developing a monotone method and using lower and upper solutions.

In [24], Al-Refai and Hajji studied the boundary value problem involving the Caputo fractional derivative with order $q\in \left(\mathrm{1,2}\right)$ ,

$D^{q}u\left(x\right)+g\left(x,u\left(x\right)\right)=0,0<x<1$

$u\left(0\right)=\alpha ,u\left(1\right)=\beta ,$

where the nonlinearity g is belonging to $\mathcal{C}\left(\left[\mathrm{0,1}\right]\times ℝ\mathrm{,}ℝ\right)$ . The authors stated existence and uniqueness of solution for the above problem under the assumption g is strictly decreasing with respect to the second variable, and $\frac{\partial g}{\partial u}$ is bounded below in some given sector.

In [25], Denton and Vatsala established new comparison results of the scalar Riemann-Liouville fractional differential equation with order $q\in \left(\mathrm{0,1}\right)$ , and proved that the system

$D^{q}u\left(x\right)=f\left(x\mathrm{,}u\left(x\right)\right)\text{in}\left(a\mathrm{,}b\right)$

$u\left(a\right)=\left(x-b\right){u\left(x\right)|}_{x=b},$

admits minimal and maximal solutions, where the nonlinearity $f\in \mathcal{C}\left(\left[a\mathrm{,}b\right]\times {ℝ}^n\mathrm{,}{ℝ}^n\right)$ . The authors suppose that the function f satisfies quasimonotone property. These results are the generalization of the results of MCRae [26]. Recently, inspired by the works of Cui [27] [28], Toumi, in [29], was concerned with the following finite system of nonlinear fractional differential equations

$D^{q}u\left(x\right)+f\left(x,u\left(x\right)\right)=0,x\in \left(0,1\right)$ (1)

$u\left(0\right)-\alpha u^{\prime }\left(0\right)=\lambda ,u\left(1\right)+\beta u^{\prime }\left(1\right)=\mu ,$ (2)

where $D^q$ is the Caputo fractional derivative with order $q\in \left(\mathrm{1,2}\right)$ . The function $f\in \mathcal{C}\left(\left[\mathrm{0,1}\right]\times {ℝ}^n\mathrm{,}{ℝ}^n\right)$ , $\lambda \mathrm{,}\mu \in {ℝ}^n$ , $\alpha \mathrm{,}\beta \in {\left({ℝ}_{+}\right)}^n$ . The author established the existence of quasi-solutions for the problem (1) and (2). Quasi-solutions are understood in the sense of Definition 7 given below. More precisely, under the hypotheses on the nonlinearity f related to the Green kernel associated with the scalar problem (1) and (2), the author constructs a pair of sequences of coupled upper and lower quasi-solutions converging uniformly to extremal quasi-solutions.

Motivated by the previous papers, we aim in this work to prove the existence of extremal quasi-solutions for (1) and (2) under more general conditions on the nonlinearity f.

This paper is organized as follows. Section 2, provides some necessary preliminaries, especially, the new comparison result for the Caputo fractional differential equation. In Section 3, we prove the existence of extremal quasi-solutions of (1) and (2). We end this work with two examples illustrating our results.

2. Preliminary Results

We start this section by recalling definitions and properties related to the Caputo fractional derivatives, then, we state the new positivity result.

Definition 1. A real function f is belonging to the space ${\mathcal{C}}_q\mathrm{,}q\in ℝ$ , if there exists $r>q$ , such that $f\left(x\right)=x^{r}h\left(x\right)$ , where the function $h\in \mathcal{C}\left(\left[\mathrm{0,}+\infty \right)\mathrm{,}ℝ\right)$ , and f is in ${\mathcal{C}}_q^n$ , if $f^{\left(n\right)}\in {\mathcal{C}}_q\mathrm{,}n\in \mathbb{N}$ .

Definition 2 (See [9] [30] ). The fractional integral of order $q>0$ for a continuous function $u\mathrm{<mo>\; :\; </mo>}\left[\mathrm{0,}+\infty \right)\to ℝ$ is defined as

$I^{q}u\left(x\right)=\frac{1}{\Gamma \left(q\right)}{\displaystyle {\int }_0^x}{\left(x-s\right)}^{q-1}u\left(s\right)\text{d}s,x>0,$

where $\Gamma$ is the Euler Gamma function.

Definition 3 (See [9] [30] ). For $q>0,n-1<q<n,n\in \mathbb{N}$ . The Caputo fractional derivative of order q for a function $u\in {\mathcal{C}}_{-1}^n$ is defined as

$D^{q}u\left(x\right)=\frac{1}{\Gamma \left(n-q\right)}{\displaystyle {\int }_0^x}{\left(x-s\right)}^{n-q-1}{u}^{\left(n\right)}\left(s\right)\text{d}s=I^{n-q}{u}^{\left(n\right)}\left(x\right).$

Next, recall the following

Lemma 1. Let $q>0$ and m be the smallest integer greater than or equal to q. Let $u\in {\mathcal{C}}^m\left(\left[\mathrm{0,1}\right]\mathrm{,}ℝ\right)$ . Then, we have

1) $D^q{I}^{q}u=u$ .

2) $D^{q}u\left(x\right)=0$ , if and only if, $u\left(x\right)={\displaystyle \underset{k=0}{\overset{m-1}{\sum }}}{c}_k{x}^k$ , where $c_k=\frac{u^{\left(k\right)}\left(0^{+}\right)}{k\mathrm{<mo>\; !\; </mo>}}$ for $k=\mathrm{0,1,}\cdots \mathrm{,}m-1$ .

3) $D^q{x}^{m-k}=0$ , for $k=\mathrm{1,2,}\cdots \mathrm{,}m$ .

For the proof of the above Lemma, and more details concerning the fractional derivative, one can refer to [30] [31].

Now we introduce below the nonlinear fractional differential equation

$D^{q}u\left(x\right)+F\left(x,u\right)=0,x\in \left(0,1\right)$ (3)

with boundary value conditions

$u\left(0\right)-\alpha u^{\prime }\left(0\right)=\lambda ,u\left(1\right)+\beta u^{\prime }\left(1\right)=\mu ,$ (4)

where $q\in \left(\mathrm{1,2}\right)\mathrm{,}\lambda \mathrm{,}\mu \in ℝ\mathrm{,}\alpha \mathrm{,}\beta \in {ℝ}_{+}$ , and the function F is in $\mathcal{C}\left(\left[\mathrm{0,1}\right]\times ℝ\mathrm{,}ℝ\right)$ .

Definition 4. A function $v\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}ℝ\right)$ is said a lower solution of (3) and (4) if it satisfies

$D^{q}v\left(x\right)+F\left(x\mathrm{,}v\right)\ge \mathrm{0,}x\in \left(\mathrm{0,1}\right)$ (5)

$v\left(0\right)-\alpha v^{\prime }\left(0\right)\le \lambda \mathrm{,}v\left(1\right)+\beta v^{\prime }\left(1\right)\le \mu$ (6)

A function $w\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}ℝ\right)$ is said an upper solution of the problem (3) and (4) if w satisfies (5) and (6) with reversed inequalities. In addition, if

$v\left(x\right)\le w\left(x\right)\mathrm{,}\text{for}\text{each}x\in \left[\mathrm{0,1}\right]\mathrm{,}$

then, the lower solution v and the upper solution w are ordered.

Next, we state a comparison result due to Syam and Al-Refai [32]

Lemma 2 (Positivity result). Let $h\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}ℝ\right)$ , and $N>0$ . Suppose that h satisfies the following inequalities

$D^{q}h\left(x\right)-Nh\left(x\right)\le \mathrm{0,}x\in (\; 0,1\; )$

$h\left(0\right)-\alpha h^{\prime }\left(0\right)\ge \mathrm{0,}h\left(1\right)+\beta h^{\prime }\left(1\right)\ge \mathrm{0,}$

where $\alpha \mathrm{,}\beta \ge 0$ . Then, we have $h\left(x\right)\ge 0$ for $x\in \left[\mathrm{0,1}\right]$ , provided that $\alpha \left(q-1\right)\ge 1$ .

3. Main Results

In the present section, we shall prove the existence of extremal quasi-solutions for the system (1) and (2). For each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ , let $r_i$ and $s_i$ be nonnegative integers satisfying $r_i+s_i=n-1$ . One can split the vector $u\in {ℝ}^n$ into $\left(u_i\mathrm{,}{\left[u\right]}_{r_i}\mathrm{,}{\left[u\right]}_{s_i}\right)$ . Thus, the Equations (1) and (2) are equivalent to

$D^q{u}_i\left(x\right)+f_i\left(x\mathrm{,}{u}_i\left(x\right)\mathrm{,}{\left[u\left(x\right)\right]}_{r_i}\mathrm{,}{\left[u\left(x\right)\right]}_{s_i}\right)=0\text{in}\left(\mathrm{0,1}\right)$ (7)

$u_i\left(0\right)-{\alpha }_i{u^{\prime }}_i\left(0\right)={\lambda }_i,u_i\left(1\right)+{\beta }_i{u^{\prime }}_i\left(1\right)={\mu }_i,$ (8)

for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Next, we recall that for $v\mathrm{,}w\in {ℝ}^n$ , $v\le w$ if and only if, $v_i\le w_i$ for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ . Define for $v\mathrm{,}w\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}{ℝ}^n\right)$ the set

$\left[v\mathrm{,}w\right]=\left\{u\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}{ℝ}^n\right)\mathrm{<mo>\; :\; </mo>}v\left(x\right)\le u\left(x\right)\le w\left(x\right)\mathrm{,}x\in \left[\mathrm{0,1}\right]\right\}\mathrm{.}$

For the sake of simplicity, we put ${\phi }_i\left(u\right)=u_i\left(0\right)-{\alpha }_i{u^{\prime }}_i\left(0\right)$ , and ${\psi }_i\left(u\right)=u_i\left(1\right)+{\beta }_i{u^{\prime }}_i\left(1\right)$ , for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Now, we introduce a crucial property, known as called quasimonotone.

Definition 5. A function $f\in \mathcal{C}\left(\left[\mathrm{0,1}\right]\times {ℝ}^n\mathrm{,}{ℝ}^n\right)$ is said to possess a mixed quasimonotone property if the function $f_i\left(t\mathrm{,}{u}_i\mathrm{,}{\left[u\right]}_{r_i}\mathrm{,}{\left[u\right]}_{s_i}\right)$ is monotone nondecreasing in ${\left[u\right]}_{r_i}$ and monotone nonincreasing in ${\left[u\right]}_{s_i}$ , for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Definition 6. Let $v\mathrm{,}w\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}{ℝ}^n\right)$ , the functions v and w are coupled lower and upper quasi-solutions of (7) and (8) if v and w satisfy

$D^q{v}_i\left(x\right)+f_i\left(x\mathrm{,}{v}_i\left(x\right)\mathrm{,}{\left[v\left(x\right)\right]}_{r_i}\mathrm{,}{\left[w\left(x\right)\right]}_{s_i}\right)\ge \mathrm{0,}x\in \left(\mathrm{0,1}\right)$ (9)

${\phi }_i\left(v\right)\le {\lambda }_i\mathrm{,}{\psi }_i\left(v\right)\le {\mu }_i\mathrm{,}$ (10)

and

$D^q{w}_i\left(x\right)+f_i\left(x\mathrm{,}{w}_i\left(x\right)\mathrm{,}{\left[w\left(x\right)\right]}_{r_i}\mathrm{,}{\left[v\left(x\right)\right]}_{s_i}\right)\le \mathrm{0,}x\in \left(\mathrm{0,1}\right)$ (11)

${\phi }_i\left(w\right)\ge {\lambda }_i\mathrm{,}{\psi }_i\left(w\right)\ge {\mu }_i\mathrm{,}$ (12)

for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Definition 7. Let $v\mathrm{,}w\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}{ℝ}^n\right)$ . The functions v and w are said a coupled of quasi-solutions of (7) and (8) if v and w satisfy

$D^q{v}_i\left(x\right)+f_i\left(x\mathrm{,}{v}_i\left(x\right)\mathrm{,}{\left[v\left(x\right)\right]}_{r_i}\mathrm{,}{\left[w\left(x\right)\right]}_{s_i}\right)=\mathrm{0,}x\in (\; 0,1\; )$

${\phi }_i\left(v\right)={\lambda }_i,{\psi }_i\left(v\right)={\mu }_i,$

and

$D^q{w}_i\left(x\right)+f_i\left(x,w_i\left(x\right),{\left[w\left(x\right)\right]}_{r_i},{\left[v\left(x\right)\right]}_{s_i}\right)=0,x\in \left(0,1\right)$

${\phi }_i\left(w\right)={\lambda }_i,{\psi }_i\left(w\right)={\mu }_i,$

for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

In the sequel, we adopt the following hypotheses

(H1) $v^0\mathrm{,}{w}^0\in {\mathcal{C}}^2\left(\left[\mathrm{0,1}\right]\mathrm{,}{ℝ}^n\right)$ are coupled lower and upper quasi-solutions of (7) and (8) satisfying $v^0\le w^0$ on $\left[\mathrm{0,1}\right]$ .

(H2) The function f possess the mixed quasimonotone property, and there exists $N\in {\left({ℝ}_{+}\right)}^n$ such that, for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ , we have

$f_i\left(x\mathrm{,}{u}_i\mathrm{,}{\left[u\right]}_{r_i}\mathrm{,}{\left[u\right]}_{s_i}\right)-f_i\left(x\mathrm{,}{z}_i\mathrm{,}{\left[u\right]}_{r_i}\mathrm{,}{\left[u\right]}_{s_i}\right)\ge -N_i\left(u_i-z_i\right)$ (13)

whenever $v^0\le z\le u\le w^0$ on $\left[\mathrm{0,1}\right]$ .

Theorem 3. Let ${\alpha }_i\left(q-1\right)\ge 1$ , for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ . Assume that (H1) and (H2) are satisfied and suppose that

(H3) $v^k\mathrm{,}{w}^k\mathrm{,}k\ge 1$ is a pair of solutions of

$D^q{v}_i^k+f_i\left(x\mathrm{,}{v}_i^{k-1}\mathrm{,}{\left[v^{k-1}\right]}_{r_i}\mathrm{,}{\left[w^{k-1}\right]}_{s_i}\right)-N_i\left(v_i^k-v_i^{k-1}\right)=\mathrm{0,}x\in \left(\mathrm{0,1}\right)$ (14)

${\phi }_i\left(v^{k-1}\right)\le {\phi }_i\left(v^k\right)\le {\lambda }_i\mathrm{,}{\psi }_i\left(v^{k-1}\right)\le {\psi }_i\left(v^k\right)\le {\mu }_i\mathrm{,}$ (15)

and

$D^q{w}_i^k+f_i\left(x\mathrm{,}{w}_i^{k-1}\mathrm{,}{\left[w^{k-1}\right]}_{r_i}\mathrm{,}{\left[v^{k-1}\right]}_{s_i}\right)-N_i\left(w_i^k-w_i^{k-1}\right)=\mathrm{0,}x\in \left(\mathrm{0,1}\right)$ (16)

${\phi }_i\left(w^{k-1}\right)\ge {\phi }_i\left(w^k\right)\ge {\lambda }_i\mathrm{,}{\psi }_i\left(w^{k-1}\right)\ge {\psi }_i\left(w^k\right)\ge {\mu }_i\mathrm{,}$ (17)

for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Then, we have the following

1) $\left(v^k\right)$ and $\left(w^k\right)$ are a couple of monotone sequences of ordered coupled of lower and upper quasi-solutions of (7) and (8).

2) The sequences $\left(v^k\right)$ and $\left(w^k\right)$ converge monotonically and uniformly to the functions $v^{\ast }$ and $w^{\ast }$ , respectively, with $v^0\le v^{\ast }\le w^{\ast }\le w^0$ on $\left[\mathrm{0,1}\right]$ . Moreover, if for $k\ge 0$ and for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ , ${\phi }_i\left(v^k\right)={\phi }_i\left(w^k\right)={\lambda }_i$ and ${\psi }_i\left(v^k\right)={\psi }_i\left(w^k\right)={\mu }_i$ . Then $v^{\ast }$ and $w^{\ast }$ are a pair of minimal and maximal quasi-solutions of (7) and (8), in $\left[v^0\mathrm{,}{w}^0\right]$ .

Proof.

1) First, we show that ${\left(v^k\right)}_{k\ge 1}$ is increasing sequence and ${\left(w^k\right)}_{k\ge 1}$ is decreasing sequence using induction arguments. For $k=1$ , we have from (14) and (16),

$D^q{v}_i^1+f_i\left(x,v_i^0,{\left[v^0\right]}_{r_i},{\left[w^0\right]}_{s_i}\right)-N_i\left(v_i^1-v_i^0\right)=0$ (18)

and

$D^q{w}_i^1+f_i\left(x,w_i^0,{\left[w^0\right]}_{r_i},{\left[v^0\right]}_{s_i}\right)-N_i\left(w_i^1-w_i^0\right)=0$ (19)

for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Since $v^0$ and $w^0$ are coupled lower and upper quasi-solutions of (7) and (8), we have

$D^q{v}_i^0+f_i\left(x\mathrm{,}{v}_i^0\mathrm{,}{\left[v^0\right]}_{r_i}\mathrm{,}{\left[w^0\right]}_{s_i}\right)\ge 0$ (20)

and

$D^q{w}_i^0+f_i\left(x\mathrm{,}{w}_i^0\mathrm{,}{\left[w^0\right]}_{r_i}\mathrm{,}{\left[v^0\right]}_{s_i}\right)\le 0$ (21)

for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Subtracting (18) from (20) and (21) from (19) we obtain

$D^q\left(v_i^1-v_i^0\right)-N_i\left(v_i^1-v_i^0\right)\le 0$ (22)

and

$D^q\left(w_i^0-w_i^1\right)-N_i\left(w_i^0-w_i^1\right)\le 0.$ (23)

Using the fact that $v^0\le w^0$ on $\left[\mathrm{0,1}\right]$ , (22) and (23) and the boundary conditions (15) and (17) for $k=1$ , we obtain for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$

$D^q{p}_i-N_i{p}_i\le 0\text{in}\left(\mathrm{0,1}\right)\mathrm{,}{\phi }_i\left(p\right)=\mathrm{0,}{\psi }_i\left(p\right)=0$ (24)

and

$D^q{z}_i-N_i{z}_i\le 0\text{in}\left(\mathrm{0,1}\right)\mathrm{,}{\phi }_i\left(z\right)=\mathrm{0,}{\psi }_i\left(z\right)=\mathrm{0,}$ (25)

where $p=v^1-v^0$ and $z=w^0-w^1$ on $\left[\mathrm{0,1}\right]$ . Applying Lemma 1 we get $v_i^1\ge v_i^0$ and $w_i^0\ge w_i^1$ on $\left[\mathrm{0,1}\right]$ for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ . So $v^1\ge v^0$ and $w^1\le w^0$ on $\left[\mathrm{0,1}\right]$ . Thus, the result is proved for $k=1$ . Next, suppose that for $j\in \left\{\mathrm{1,}\cdots \mathrm{,}k\right\}$

$v^{j-1}\le v^j\text{and}{w}^j\le w^{j-1}\text{on}\left[\mathrm{0,1}\right]\mathrm{.}$ (26)

From (14), we get

$D^q{v}_i^{k+1}+f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)-N_i\left(v_i^{k+1}-v_i^k\right)=0$ (27)

and

$D^q{v}_i^k+f_i\left(x\mathrm{,}{v}_i^{k-1}\mathrm{,}{\left[v^{k-1}\right]}_{r_i}\mathrm{,}{\left[w^{k-1}\right]}_{s_i}\right)-N_i\left(v_i^k-v_i^{k-1}\right)=0$ (28)

for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ .

Subtracting (28) from (27), we obtain

$\begin{array}{l}{D}^q\left(v_i^{k+1}-v_i^k\right)-N_i\left(v_i^{k+1}-v_i^k\right)\\ =f_i\left(x,v_i^{k-1},{\left[v^{k-1}\right]}_{r_i},{\left[w^{k-1}\right]}_{s_i}\right)-f_i\left(x,v_i^k,{\left[v^k\right]}_{r_i},{\left[w^k\right]}_{s_i}\right)-N_i\left(v_i^k-v_i^{k-1}\right).\end{array}$

Now using the induction’s hypothesis (26), and the mixed monotone property of f, we obtain

$\begin{array}{l}{D}^q\left(v_i^{k+1}-v_i^k\right)-N_i\left(v_i^{k+1}-v_i^k\right)\\ \le f_i\left(x\mathrm{,}{v}_i^{k-1}\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^{k-1}\right]}_{s_i}\right)-f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^{k-1}\right]}_{s_i}\right)-N_i\left(v_i^k-v_i^{k-1}\right)\mathrm{.}\end{array}$

So, hypothesis (H2) yields

$D^q\left(v_i^{k+1}-v_i^k\right)-N_i\left(v_i^{k+1}-v_i^k\right)\le N_i\left(v_i^{k-1}-v_i^k\right)+N_i\left(v_i^k-v_i^{k-1}\right)=0.$ (29)

Therefore, using (29) and the boundary conditions (15) and (17) for $j=k+1$ , we obtain

$\begin{array}{l}{D}^q\left(v_i^{k+1}-v_i^k\right)-N_i\left(v_i^{k+1}-v_i^k\right)\le 0\text{in}\left(\mathrm{0,1}\right)\mathrm{,}\\ {\phi }_i\left(v^{k+1}-v^k\right)\ge \mathrm{0,}{\psi }_i\left(v^{k+1}-v^k\right)\ge 0.\end{array}$

Let $p=v_i^{k+1}-v_i^k$ , by Lemma 1 we have $p\ge 0$ and so $v_i^{k+1}\ge v_i^k$ for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ . Hence $v^{k+1}\ge v^k$ on $\left[\mathrm{0,1}\right]$ . Similarly, we obtain $w^k\le w^{k+1}$ on $\left[\mathrm{0,1}\right]$ . Whence, we verify the result for $j=k+1$ .

Now, let us prove that, for each $k\ge 1$ , the pair $v^k$ and $w^k$ are an ordered coupled lower and upper quasi-solutions of (7) and (8). By adding $f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)$ to both sides of (14), we get for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$

$\begin{array}{l}{D}^q\left(v_i^k\right)+f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)\\ =f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)-f_i\left(x\mathrm{,}{v}_i^{k-1}\mathrm{,}{\left[v^{k-1}\right]}_{r_i}\mathrm{,}{\left[w^{k-1}\right]}_{s_i}\right)+N_i\left(v_i^k-v_i^{k-1}\right)\end{array}$

Using the fact that $v_i^k\ge v_i^{k-1}$ and $w_i^{k-1}\ge w_i^k$ and the property of the function f, it follows that

$\begin{array}{l}{D}^q\left(v_i^k\right)+f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)\\ \ge f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^{k-1}\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)-f_i\left(x\mathrm{,}{v}_i^{k-1}\mathrm{,}{\left[v^{k-1}\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)+N_i\left(v_i^k-v_i^{k-1}\right)\end{array}$

So, by hypothesis (H2), we conclude

$D^q\left(v_i^k\right)+f_i\left(x\mathrm{,}{v}_i^k\mathrm{,}{\left[v^k\right]}_{r_i}\mathrm{,}{\left[w^k\right]}_{s_i}\right)\ge 0$

Similarly, we prove that

$D^q\left(w_i^k\right)+f_i\left(x\mathrm{,}{w}_i^k\mathrm{,}{\left[w^k\right]}_{r_i}\mathrm{,}{\left[v^k\right]}_{s_i}\right)\le 0$

which together with (15) and (17) prove that $\left(v^k\mathrm{,}{w}^k\right)$ is pair of coupled lower and upper quasi-solutions of (7) and (8).

Now, we shall prove that $v^k$ and $w^k$ are ordered. We use induction arguments. For $k=1$ , by subtracting (18) from (19) we get

$\begin{array}{l}{D}^q\left(w_i^1-v_i^1\right)-N_i\left(w_i^1-v_i^1\right)\\ =f_i\left(x,v_i^0,{\left[v^0\right]}_{r_i},{\left[w^0\right]}_{s_i}\right)-f_i\left(x,w_i^0,{\left[w^0\right]}_{r_i},{\left[v^0\right]}_{s_i}\right)-N_i\left(w_i^0-v_i^0\right).\end{array}$

Using hypothesis (H1), and the mixed-monotone property of f, we obtain

$\begin{array}{l}{D}^q\left(w_i^1-v_i^1\right)-N_i\left(w_i^1-v_i^1\right)\\ \le f_i\left(x\mathrm{,}{v}_i^0\mathrm{,}{\left[w^0\right]}_{r_i}\mathrm{,}{\left[w^0\right]}_{s_i}\right)-f_i\left(x\mathrm{,}{w}_i^0\mathrm{,}{\left[w^0\right]}_{r_i}\mathrm{,}{\left[w^0\right]}_{s_i}\right)-N_i\left(w_i^0-v_i^0\right)\mathrm{,}\end{array}$

which by hypothesis (H2) yields

$D^q\left(w_i^1-v_i^1\right)-N_i\left(w_i^1-v_i^1\right)\le 0.$

From (15) and (17), we obtain ${\phi }_i\left(w^1-v^1\right)\ge 0$ and ${\psi }_i\left(w^1-v^1\right)\ge 0$ . Let $z=w_i^1-v_i^1$ , then by Lemma 1, we obtain $z\ge 0$ for i, $1\le i\le n$ , so $w^1\ge v^1$ . Next, assume that we have for any j in $\left\{\mathrm{1,}\cdots \mathrm{,}k\right\}$

$v^j\le w^j\mathrm{.}$ (30)

Similarly, by hypothesis (H2) and (30) we have

$\begin{array}{l}{D}^q\left(w_i^{k+1}-v_i^{k+1}\right)-N_i\left(w_i^{k+1}-v_i^{k+1}\right)\\ \le f_i\left(x,v_i^k,{\left[v^k\right]}_{r_i},{\left[w^k\right]}_{s_i}\right)-f_i\left(x,w_i^k,{\left[w^k\right]}_{r_i},{\left[v^k\right]}_{s_i}\right)-N_i\left(w_i^k-v_i^k\right)\\ \le f_i\left(x,v_i^k,{\left[w^k\right]}_{r_i},{\left[w^k\right]}_{s_i}\right)-f_i\left(x,w_i^k,{\left[w^k\right]}_{r_i},{\left[w^k\right]}_{s_i}\right)-N_i\left(w_i^k-v_i^k\right)\le 0.\end{array}$

On the other hand, from (15) and (17), we obtain ${\phi }_i\left(w^{k+1}-v^{k+1}\right)\ge 0$ and ${\psi }_i\left(w^{k+1}-v^{k+1}\right)\ge 0$ . Let $z=w_i^{k+1}-v_i^{k+1}$ , then by Lemma 1, we obtain $z\ge 0$ for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ . Thus $v^{k+1}\le w^{k+1}$ .

2) For each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ , the sequences $\left(v_i^k\right)$ and $\left(w_i^k\right)$ are uniformly bounded and equicontinuous. Thus, using Arzela-Ascoli’s Theorem, we deduce that ${\lim }_{k\to +\infty }{v}_i^k=v_i^{\ast }$ and ${\lim }_{k\to +\infty }{w}_i^k=w_i^{\ast }$ . Since, in this case, the pointwise convergence yields to the uniform one, we deduce that $\left(v_i^k\right)$ and $\left(w_i^k\right)$ converge uniformly on $\left[\mathrm{0,1}\right]$ and so $\left(v^k\right)$ and $\left(w^k\right)$ converge uniformly to $v^{\ast }$ and $w^{\ast }$ , respectively.

Now, by using the fact that $v_0\le v^k\le w^k\le w_0$ for each $k\ge 1$ and letting $k\to \infty$ we conclude that $v^{\ast }\le w^{\ast }$ .

Next, let us prove that $\left(v^{\ast }\mathrm{,}{w}^{\ast }\right)$ is pair a of quasi-solutions of (7) and (8). From (14)

$D^q{v}_i^k+f_i\left(x,v_i^{k-1},{\left[v^{k-1}\right]}_{r_i},{\left[w^{k-1}\right]}_{s_i}\right)-N_i\left(v_i^k-v_i^{k-1}\right)=0$

Applying the operator $I^q$ and using Lemma 1 (2), we obtain

$v_i^k-c_0^k-c_1^{k}x+I^q{f}_i\left(x,v_i^{k-1},{\left[v^{k-1}\right]}_{r_i},{\left[w^{k-1}\right]}_{s_i}\right)-N_i\left(I^q{v}_i^k-I^q{v}_i^{k-1}\right)=0.$

Since $v^k\to v^{\ast }$ and $w^k\to w^{\ast }$ uniformly when $k\to +\infty$ and the function f is continuous, we obtain, for each $i=\mathrm{1,2,}\cdots \mathrm{,}n$ ,

$v_i^{\ast }-c_0^{\ast }-c_1^{\ast }x+I^q{f}_i\left(x,v_i^{\ast },{\left[v^{\ast }\right]}_{r_i},{\left[w^{\ast }\right]}_{s_i}\right)=0$ (31)

where $c_0^{\ast }=v_i^{\ast }\left(0\right)={\lim }_{k\to \infty }{v}_i^k\left(0\right)$ and $c_1^{\ast }={\lim }_{k\to \infty }{\left(v_i^k\right)}^{\prime }\left(0\right)$ . Now, applying $D^q$ to (31) and using Lemma 1 (1) and (3), we obtain,

$D^q{v}_i^{\ast }+f_i\left(x,v_i^{\ast },{\left[v^{\ast }\right]}_{r_i},{\left[w^{\ast }\right]}_{s_i}\right)=0.$ (32)

In addition, it is easy to verify that ${\phi }_i\left(v^{\ast }\right)={\lambda }_i,{\psi }_i\left(v^{\ast }\right)={\mu }_i$ . So $v^{\ast }$ satisfies (9) and (10), in the same manner, we prove that $w^{\ast }$ satisfies (11) and (12). Therefore, $v^{\ast }$ and $w^{\ast }$ are coupled quasi-solutions of (7) and (8) in $\left[v^0\mathrm{,}{w}^0\right]$ .

Now, let us prove that the functions $v^{\ast }$ and $w^{\ast }$ are a pair of minimal-maximal coupled quasi-solutions of the problem (7) and (8) in $\left[v^0\mathrm{,}{w}^0\right]$ . Let $v\mathrm{,}w\in \left[v^0\mathrm{,}{w}^0\right]$ be a pair of coupled quasi-solutions of (7) and (8). We will proceed by induction. First, it is obvious to see that $v\ge v^0$ , and $w\le w^0$ . Assume that

$v\ge v^k\text{and}w\le w^k\text{on}\left[\mathrm{0,1}\right]$ (33)

is true. Thus, using (33), we obtain

$\begin{array}{l}{D}^q\left(v_i-v_i^{k+1}\right)-N_i\left(v_i-v_i^{k+1}\right)\\ =f_i\left(x,v_i^k,{\left[v^k\right]}_{r_i},{\left[w^k\right]}_{s_i}\right)-f_i\left(x,v_i,{\left[v\right]}_{r_i},{\left[w\right]}_{s_i}\right)+N_i\left(v_i^k-v_i\right)\\ \le f_i\left(x,v_i^k,{\left[v\right]}_{r_i},{\left[w\right]}_{s_i}\right)-f_i\left(x,v_i,{\left[v\right]}_{r_i},{\left[w\right]}_{s_i}\right)+N_i\left(v_i^k-v_i\right)\end{array}$

So, by hypothesis (H2), we conclude

$D^q\left(v_i-v_i^{k+1}\right)-N_i\left(v_i-v_i^{k+1}\right)\le 0.$

From (15), we obtain ${\phi }_i\left(v-v^{k+1}\right)\ge 0$ and ${\psi }_i\left(v-v^{k+1}\right)\ge 0$ . Put $z=v_i-v_i^{k+1}$ , then by Lemma 1, we have $z\ge 0$ for each $i=1,2,\cdots ,n$ , so $v\ge v^{k+1}$ . In the same manner, we prove that $w\le w^{k+1}$ . Thus, taking limit $k\to +\infty$ , we get

$v\ge v^{\ast }\text{and}w\le w^{\ast }\mathrm{.}$

That is, $v^{\ast }\mathrm{,}{w}^{\ast }$ are minimal-maximal coupled quasi-solutions of the problem (7) and (8) in $\left[v^0\mathrm{,}{w}^0\right]$ . This ends the proof.

Remark 1. We remark that if $n=1$ then $s_i=r_i=0$ , and so (7) and (8) is reduced to the scalar boundary value problem. In this case, Theorem 2 improves the result in [24].

Remark 2. Note that, if, for each $i=1,\cdots ,n$ , $r_i=n-1$ , $s_i=0$ . Then, we obtain minimal and maximal solutions of (7) and (8). Hence, Theorem 1 covers the case of quasimonotone nondecreasing nonlinearity.

We state uniqueness result in the following

Theorem 4. Assume that assumptions (H1) - (H3) hold. Moreover, suppose that, for each $i=1,2,\cdots ,n$ , $L_i>0$ and

$f_i\left(x\mathrm{,}{u}_i\mathrm{,}{\left[u\right]}_{r_i}\mathrm{,}{\left[v\right]}_{s_i}\right)-f_i\left(x\mathrm{,}{v}_i\mathrm{,}{\left[v\right]}_{r_i}\mathrm{,}{\left[u\right]}_{s_i}\right)\le -L_i\left(u_i-v_i\right)$

on $\left[\mathrm{0,1}\right]$ , for any v, $v^0\le v\le u\le w^0$ . Then, the problem (7) and (8) admits a unique solution in $\left[v^0\mathrm{,}{w}^0\right]$ .

Proof. Since $v^{\ast }\le w^{\ast }$ , we need only to prove that $w^{\ast }\le v^{\ast }$ on $\left[\mathrm{0,1}\right]$ . Let $z_i=v_i^{\ast }-w_i^{\ast }$ on $\left[\mathrm{0,1}\right]$ for each $i=1,\cdots ,n$ . Then we get

$D^q{z}_i=f_i\left(x\mathrm{,}{w}_i^{\ast }\mathrm{,}{\left[w^{\ast }\right]}_{r_i}\mathrm{,}{\left[v^{\ast }\right]}_{s_i}\right)-f_i\left(x\mathrm{,}{v}_i^{\ast }\mathrm{,}{\left[v^{\ast }\right]}_{r_i}\mathrm{,}{\left[w^{\ast }\right]}_{s_i}\right)\le L_i\left(v_i^{\ast }-w_i^{\ast }\right)\mathrm{.}$

So, we conclude

$D^q{z}_i-L_i{z}_i\le 0.$

Since ${\phi }_i\left(v^{\ast }\right)={\phi }_i\left(w^{\ast }\right)={\lambda }_i$ , and ${\psi }_i\left(v^{\ast }\right)={\psi }_i\left(w^{\ast }\right)={\mu }_i$ . Then ${\phi }_i\left(z\right)=0$ and ${\psi }_i\left(z\right)=0$ . Therefore, by Lemma 1, we have $z_i\ge 0$ for each $i=1,2,\cdots ,n$ , which implies $w^{\ast }\le v^{\ast }$ on $\left[\mathrm{0,1}\right]$ . So, $v^{\ast }=w^{\ast }$ is the unique solution of (7) and (8) in $\left[v^0\mathrm{,}{w}^0\right]$ , which ends the proof.

Remark 3. It is worth mentioning that one can generate a numerical approximation of $v^{\ast }\mathrm{,}{w}^{\ast }$ the minimal-maximal coupled quasi-solutions of the problem (7) and (8) in $\left[v^0\mathrm{,}{w}^0\right]$ for a given coupled lower and upper quasi-solutions.

4. Examples

This section is devoted to some examples to illustrate our results.

Example 1. We consider the following nonlinear problem

$\{\begin{array}{l}{D}^{\frac{3}{2}}u\left(x\right)-u^2\left(x\right)=0,x\in \left(0,1\right)\\ u\left(0\right)-2u^{\prime }\left(0\right)=0,u\left(1\right)=1\end{array}$ (34)

So, $n=1,q=\frac{3}{2},\alpha =2,\beta =\lambda =0,\mu =1$ and $f\left(t\mathrm{,}u\right)=-u^2$ . First, condition $\alpha \left(q-1\right)\ge 1$ is satisfied. The pair $v^0\left(x\right)=0$ and $w^0\left(x\right)=1$ are ordered coupled lower and upper quasi-solutions of (34), so (H1) is verified. Moreover, we have for $N=2$ , the hypothesis (H2) holds. Next, define for each $k\ge 1$ , the sequences $v^k\left(x\right)$ and $w^k\left(x\right)$ , respectively, by

$v^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x\mathrm{,}y\right)\left(2v^{k-1}\left(y\right)-{\left(v^{k-1}\left(y\right)\right)}^2\right)-2v^k\left(y\right)\text{d}y$

and

$w^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x,y\right)\left(2w^{k-1}\left(y\right)-{\left(w^{k-1}\left(y\right)\right)}^2\right)-2w^k\left(y\right)\text{d}y,$

where

$k\left(x,y\right)=\frac{1}{3\Gamma \left(\frac{3}{2}\right)}\{\begin{array}{l}\left(2+x\right)\sqrt{1-y},0\le x\le y\\ \left(2+x\right)\sqrt{1-y}-3\sqrt{x-y},y<x\le 1\end{array}$ (35)

By Lemma 2 in [29], the sequences $v^k\left(x\right)$ and $w^k\left(x\right)$ satisfy the linear problems

$\{\begin{array}{l}{D}^{\frac{3}{2}}{v}^k+\left(2v^{k-1}-{\left(v^{k-1}\right)}^2\right)-2v^k=0\text{in}\left(\mathrm{0,1}\right)\\ v^k\left(0\right)-2{\left(v^k\right)}^{\prime }\left(0\right)=\mathrm{0,}{v}^k\left(1\right)=1\end{array}$

and

$\{\begin{array}{l}{D}^{\frac{3}{2}}{w}^k+\left(2w^{k-1}-{\left(w^{k-1}\right)}^2\right)-2w^k=0\text{in}\left(\mathrm{0,1}\right)\\ w^k\left(0\right)-2{\left(w^k\right)}^{\prime }\left(0\right)=0,w^k\left(1\right)=1\end{array}$

Thus, the hypothesis (H3) is satisfied. Hence, Theorem 1 ensures the existence of minimal and maximal solutions of (34) in $\left[\mathrm{0,1}\right]$ .

Example 2. Let f be in $\mathcal{C}\left(\left[\mathrm{0,1}\right]\times {ℝ}^3\mathrm{,}{ℝ}^3\right)$ , and defined by $f=\left(f_1\mathrm{,}{f}_2\mathrm{,}{f}_3\right)$ , where

$\begin{array}{l}{f}_1\left(x,u_1,u_2,u_3\right)={\text{e}}^{-u_3}-3u_1+u_2^2\\ f_2\left(x,u_1,u_2,u_3\right)=u_2-4u_1+u_3^2\\ f_3\left(x,u_1,u_2,u_3\right)={\text{e}}^{-u_3}-u_1-u_2\end{array}$

In this example, we deal with the following nonlinear problem

$\{\begin{array}{l}{D}^{\frac{3}{2}}u\left(x\right)+f\left(x\mathrm{,}u\left(x\right)\right)=0\text{in}\left(\mathrm{0,1}\right)\\ u\left(0\right)-\alpha u^{\prime }\left(0\right)=\lambda ,u\left(1\right)=\mu ,\end{array}$ (36)

where, $n=3,q=\frac{3}{2},\alpha =\left(2,2,2\right),\lambda =\left(0,0,0\right)$ and $\mu =\left(1,1,1\right)$ . For each

$i=1,2,3$ , the condition ${\alpha }_i\left(q-1\right)\ge 1$ is satisfied. It is easy to verify that the pair $v^0\left(x\right)=\left(0,0,0\right)$ and $w^0\left(x\right)=\left(1,1,1\right)$ are ordered coupled lower and upper quasi-solutions of (36). Now, let us verify (H2). For $i=1$ we take $r_1=1,s_1=1$ . So the function $f_1\left(x\mathrm{,}{u}_1\mathrm{,}{u}_2\mathrm{,}{u}_3\right)$ is nondecreasing in $u_2$ and nonincreasing in $u_3$ . Moreover, for $N_1=3$ , condition (13) holds. For $i=2$ we take $r_2=2,s_1=0$ . So the function $f_2\left(x\mathrm{,}{u}_2\mathrm{,}{u}_1\mathrm{,}{u}_3\right)$ is nondecreasing in $\left(u_1\mathrm{,}{u}_3\right)$ and for $N_2=4$ , condition (13) holds. For $i=3$ we take $r_3=0,s_3=2$ . So the function $f_3\left(x\mathrm{,}{u}_1\mathrm{,}{u}_2\mathrm{,}{u}_3\right)$ is nonincreasing in $\left(u_2\mathrm{,}{u}_3\right)$ and for $N_3=1$ , the condition (13) holds. Thus (H2) is satisfied. Now, let us define for $k\ge 1$ , the sequences $v^k\left(x\right)$ and $w^k\left(x\right)$ , by

$v_1^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x\mathrm{,}y\right)\mathrm{<mo\; stretchy="false">\; (\; </mo>}{f}_1\left(y\mathrm{,}{v}_1^{k-1}\mathrm{,}{v}_2^{k-1}\mathrm{,}{w}_3^{k-1}\right)+3v_1^{k-1}\mathrm{<mo\; stretchy="false">\; )\; </mo>}-3v_1^k\text{d}y\mathrm{,}$

$v_2^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x\mathrm{,}y\right)\left(f_2\left(y\mathrm{,}{v}_2^{k-1}\mathrm{,}{v}_1^{k-1}\mathrm{,}{v}_3^{k-1}\right)+4v_2^{k-1}\right)-4v_2^k\text{d}y\mathrm{,}$

$v_3^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x\mathrm{,}y\right)\left(f_3\left(y\mathrm{,}{v}_3^{k-1}\mathrm{,}{w}_1^{k-1}\mathrm{,}{w}_3^{k-1}\right)+v_3^{k-1}\right)-v_3^k\text{d}y$

and

$w_1^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x\mathrm{,}y\right)\left(f_1\left(y\mathrm{,}{w}_1^{k-1}\mathrm{,}{w}_2^{k-1}\mathrm{,}{v}_3^{k-1}\right)+3w_1^{k-1}\right)-3w_1^k\text{d}y\mathrm{,}$

$w_2^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x\mathrm{,}y\right)\left(f_2\left(y\mathrm{,}{w}_2^{k-1}\mathrm{,}{w}_1^{k-1}\mathrm{,}{w}_3^{k-1}\right)+4w_2^{k-1}\right)-4w_2^k\text{d}y\mathrm{,}$

$w_3^k\left(x\right)=\frac{2}{3}\left(1+x\right)+{\displaystyle {\int }_0^1}k\left(x\mathrm{,}y\right)\left(f_3\left(y\mathrm{,}{w}_3^{k-1}\mathrm{,}{v}_1^{k-1}\mathrm{,}{v}_3^{k-1}\right)+w_3^{k-1}\right)-w_3^k\text{d}y\mathrm{,}$

where $k\left(x\mathrm{,}y\right)$ is defined by (35).

Using Lemma 2 in [29], the sequences $v^k\left(x\right)$ and $w^k\left(y\right)$ satisfy (14) - (17). Therefore, the hypothesis (H3) is satisfied. Hence, Theorem 1 assures the existence of minimal-maximal coupled quasi-solutions of (36) in $\left[v^0\mathrm{,}{w}^0\right]$ .

Acknowledgements

This work was supported by the King Faisal University, through The Deanship of Scientific Research (Grant No. 2933).