Positive solutions for a system of semipositone coupled fractional boundary value problems

We study the existence of positive solutions for a system of nonlinear Riemann-Liouville fractional differential equations with sign-changing nonlinearities, subject to coupled integral boundary conditions.

Fractional differential equations describe many phenomena in various fields of engineering and scientific disciplines such as physics, biophysics, chemistry, biology, economics, control theory, signal and image processing, aerodynamics, viscoelasticity, electromagnetics, and so on (see [1–6]). Integral boundary conditions arise in thermal conduction problems, semiconductor problems and hydrodynamic problems.

We consider the system of nonlinear fractional differential equations

with the coupled integral boundary conditions

where \(n, m\in\mathbb{N}\), \(n, m\ge3\), \(D_{0+}^{\alpha}\), and \(D_{0+}^{\beta}\) denote the Riemann-Liouville derivatives of orders α and β, respectively, the integrals from (BC) are Riemann-Stieltjes integrals, and f, g are sign-changing continuous functions (that is, we have a so-called system of semipositone boundary value problems). These functions may be nonsingular or singular at \(t=0\) and/or \(t=1\). The boundary conditions above include multi-point and integral boundary conditions and sum of these in a single framework.

We present intervals for parameters λ and μ such that the above problem (S)-(BC) has at least one positive solution. By a positive solution of problem (S)-(BC) we mean a pair of functions \((u,v)\in C([0,1])\times C([0,1])\) satisfying (S) and (BC) with \(u(t)\ge0\), \(v(t)\ge0\) for all \(t\in[0,1]\) and \(u(t)>0\), \(v(t)>0\) for all \(t\in(0,1)\). In the case when f and g are nonnegative, problem (S)-(BC) has been investigated in [7] by using the Guo-Krasnosel’skii fixed point theorem, and in [8] where \(\lambda=\mu=1\) and \(f(t,u,v)\) and \(g(t,u,v)\) are replaced by \(\tilde{f}(t,v)\) and \(\tilde{g}(t,u)\), respectively (denoted by (S̃)). In [8], the authors study two cases: f and g are nonsingular and singular functions and they used some theorems from the fixed point index theory and the Guo-Krasnosel’skii fixed point theorem. The systems (S) and (S̃) with uncoupled boundary conditions

were investigated in [9] (problem (S)-(BC̃) with f, g nonnegative), in [10] (problem (S̃)-(BC̃) with f, g nonnegative, singular or not), and in [11] (problem (S)-(BC̃) with f, g sign-changing functions). We also mention paper [12], where the authors studied the existence and multiplicity of positive solutions for system (S) with \(\alpha=\beta\), \(\lambda=\mu \), and the boundary conditions \(u^{(i)}(0)=v^{(i)}(0)=0\), \(i=0,\ldots ,n-2\), \(u(1)=av(\xi)\), \(v(1)=b u(\eta)\), \(\xi, \eta\in(0,1)\), with \(\xi , \eta\in(0,1)\), \(0< ab\xi\eta<1\), and f, g are sign-changing nonsingular or singular functions.

The paper is organized as follows. Section 2 contains some preliminaries and lemmas. The main results are presented in Section 3, and finally in Section 4 some examples are given to support the new results.

We present here the definitions of Riemann-Liouville fractional integral and Riemann-Liouville fractional derivative and then some auxiliary results that will be used to prove our main results.

Definition 2.1

The (left-sided) fractional integral of order \(\alpha>0\) of a function \(f:(0,\infty)\to\mathbb{R}\) is given by

provided the right-hand side is pointwise defined on \((0,\infty)\), where \(\Gamma(\alpha)\) is the Euler gamma function defined by \(\Gamma (\alpha)= \int_{0}^{\infty}t^{\alpha-1}e^{-t} \,dt\), \(\alpha>0\).

Definition 2.2

The Riemann-Liouville fractional derivative of order \(\alpha\ge0\) for a function \(f:(0,\infty)\to\mathbb{R}\) is given by

where \(n=\lfloor\alpha\rfloor+1\), provided that the right-hand side is pointwise defined on \((0,\infty)\).

The notation \(\lfloor\alpha\rfloor\) stands for the largest integer not greater than α. If \(\alpha=m\in\mathbb{N}\) then \(D_{0+}^{m}f(t)=f^{(m)}(t)\) for \(t>0\), and if \(\alpha=0\) then \(D_{0+}^{0}f(t)=f(t)\) for \(t>0\).

We consider now the fractional differential system

with the coupled integral boundary conditions

where \(n, m\in\mathbb{N}\), \(n, m\ge3\), and \(H, K:[0,1]\to\mathbb{R}\) are functions of bounded variation.

Lemma 2.1

([7])

If \(H, K:[0,1]\to\mathbb{R}\) are functions of bounded variations, \(\Delta=1- (\int_{0}^{1}\tau^{\alpha-1} \,dK(\tau) ) (\int_{0}^{1}\tau^{\beta -1} \,dH(\tau) )\neq0\) and \(\tilde{x}, \tilde{y}\in C(0,1)\cap L^{1}(0,1)\), then the pair of functions \((u,v)\in C([0,1])\times C([0,1])\) given by

where

and

is solution of problem (1)-(2).

Lemma 2.2

The functions \(g_{1}\), \(g_{2}\) given by (5) have the properties:

(a):

\(g_{1}, g_{2}:[0,1]\times[0,1]\to\mathbb{R}_{+}\) are continuous functions, and \(g_{1}(t,s)>0\), \(g_{2}(t,s)>0\) for all \((t,s)\in(0,1)\times(0,1)\).

(b):

\(g_{1}(t,s)\le h_{1}(s)\), \(g_{2}(t,s)\le h_{2}(s)\) for all \((t,s)\in [0,1]\times[0,1]\), where \(h_{1}(s)=\frac{s(1-s)^{\alpha-1}}{\Gamma(\alpha -1)}\) and \(h_{2}(s)=\frac{s(1-s)^{\beta-1}}{\Gamma(\beta-1)}\) for all \(s\in[0,1]\).

(c):

\(g_{1}(t,s)\ge k_{1}(t)h_{1}(s)\), \(g_{2}(t,s)\ge k_{2}(t)h_{2}(s)\) for all \((t,s)\in[0,1]\times[0,1]\), where

$$\begin{aligned}& k_{1}(t)=\min \biggl\{ \frac{(1-t)t^{\alpha-2}}{\alpha -1},\frac{t^{\alpha-1}}{\alpha-1} \biggr\} =\left \{ \textstyle\begin{array}{l@{\quad}l}\frac{t^{\alpha-1}}{\alpha-1},&0\le t\le\frac{1}{2}, \\ \frac{(1-t)t^{\alpha-2}}{\alpha-1},&\frac{1}{2}\le t\le1, \end{array}\displaystyle \right . \\& k_{2}(t)=\min \biggl\{ \frac{(1-t)t^{\beta-2}}{\beta-1},\frac{t^{\beta -1}}{\beta-1} \biggr\} = \left \{ \textstyle\begin{array}{l@{\quad}l}\frac{t^{\beta-1}}{\beta-1},&0\le t\le\frac{1}{2}, \\ \frac{(1-t)t^{\beta-2}}{\beta-1},&\frac{1}{2}\le t\le1. \end{array}\displaystyle \right . \end{aligned}$$

(d):

For any \((t,s)\in[0,1]\times[0,1]\), we have

$$g_{1}(t,s)\le\frac{(1-t)t^{\alpha-1}}{\Gamma(\alpha-1)}\le\frac{t^{\alpha -1}}{\Gamma(\alpha-1)},\qquad g_{2}(t,s)\le\frac{(1-t)t^{\beta-1}}{\Gamma(\beta-1)}\le\frac{t^{\beta -1}}{\Gamma(\beta-1)}. $$

For the proof of Lemma 2.2(a) and (b) see [13], for the proof of Lemma 2.2(c) see [11], and the proof of Lemma 2.2(d) is based on the relations \(g_{1}(t,s)=g_{1}(1-s,1-t)\), \(g_{2}(t,s)=g_{2}(1-s,1-t)\), and relations (b) above.

Lemma 2.3

([7])

If \(H, K:[0,1]\to\mathbb{R}\) are nondecreasing functions, and \(\Delta>0\), then \(G_{i}\), \(i=1,\ldots,4\) given by (4) are continuous functions on \([0,1]\times[0,1]\) and satisfy \(G_{i}(t,s)\ge0\) for all \((t,s)\in[0,1]\times[0,1]\), \(i=1,\ldots,4\). Moreover, if \(\tilde{x}, \tilde{y}\in C(0,1)\cap L^{1}(0,1)\) satisfy \(\tilde{x}(t)\ge0\), \(\tilde{y}(t)\ge0\) for all \(t\in(0,1)\), then the solution \((u,v)\) of problem (1)-(2) given by (3) satisfies \(u(t)\ge0\), \(v(t)\ge0\) for all \(t\in[0,1]\).

Lemma 2.4

Assume that \(H, K:[0,1]\to\mathbb{R}\) are nondecreasing functions, \(\Delta>0\), \(\int_{0}^{1}\tau^{\alpha-1}(1-\tau) \,dK(\tau)>0\), \(\int_{0}^{1}\tau^{\beta-1}(1-\tau) \,dH(\tau)>0\). Then the functions \(G_{i}\), \(i=1,\ldots,4\) satisfy the inequalities:

(a₁):

\(G_{1}(t,s)\le\sigma_{1} h_{1}(s)\), \(\forall(t,s)\in[0,1]\times [0,1]\), where

$$\sigma_{1}=1+ \frac{1}{\Delta}\bigl(K(1)-K(0)\bigr) \int_{0}^{1}\tau^{\beta-1} \,dH(\tau)>0. $$

(a₂):

\(G_{1}(t,s)\le\delta_{1} t^{\alpha-1}\), \(\forall(t,s)\in [0,1]\times[0,1]\), where

$$\delta_{1}= \frac{1}{\Gamma(\alpha-1)} \biggl[1+ \frac{1}{\Delta} \biggl( \int _{0}^{1}\tau^{\beta-1} \,dH(\tau) \biggr) \biggl( \int_{0}^{1}(1-\tau)\tau^{\alpha -1} \,dK(\tau) \biggr) \biggr]>0. $$

(a₃):

\(G_{1}(t,s)\ge\varrho_{1} t^{\alpha-1} h_{1}(s)\), \((t,s)\in [0,1]\times[0,1]\), where

$$\varrho_{1}= \frac{1}{\Delta} \biggl( \int_{0}^{1}\tau^{\beta-1} \,dH(\tau) \biggr) \biggl( \int_{0}^{1} k_{1}(\tau) \,dK(\tau) \biggr)>0. $$

(b₁):

\(G_{2}(t,s)\le\sigma_{2} h_{2}(s)\), \(\forall (t,s)\in[0,1]\times [0,1]\), where \(\sigma_{2}=\frac{1}{\Delta}(H(1)-H(0))>0\).

(b₂):

\(G_{2}(t,s)\le\delta_{2} t^{\alpha-1}\), \(\forall(t,s)\in [0,1]\times[0,1]\), where \(\delta_{2}=\frac{1}{\Delta\Gamma(\beta-1)}\int _{0}^{1}(1-\tau)\tau^{\beta-1} \,dH(\tau)>0\).

(b₃):

\(G_{2}(t,s)\ge\varrho_{2} t^{\alpha-1}h_{2}(s)\), \(\forall(t,s)\in [0,1]\times[0,1]\), where \(\varrho_{2}=\frac{1}{\Delta}\int_{0}^{1}k_{2}(\tau) \,dH(\tau)>0\).

(c₁):

\(G_{3}(t,s)\le\sigma_{3} h_{2}(s)\), \(\forall(t,s)\in[0,1]\times [0,1]\), where

$$\sigma_{3}=1+ \frac{1}{\Delta}\bigl(H(1)-H(0)\bigr) \int_{0}^{1}\tau^{\alpha-1} \,dK(\tau)>0. $$

(c₂):

\(G_{3}(t,s)\le\delta_{3} t^{\beta-1}\), \(\forall(t,s)\in[0,1]\times [0,1]\), where

$$\delta_{3}= \frac{1}{\Gamma(\beta-1)} \biggl[1+ \frac{1}{\Delta} \biggl( \int _{0}^{1}\tau^{\alpha-1} \,dK(\tau) \biggr) \biggl( \int_{0}^{1}(1-\tau)\tau^{\beta -1} \,dH(\tau) \biggr) \biggr]>0. $$

(c₃):

\(G_{3}(t,s)\ge\varrho_{3} t^{\beta-1} h_{2}(s)\), \(\forall(t,s)\in [0,1]\times[0,1]\), where

$$\varrho_{3}= \frac{1}{\Delta} \biggl( \int_{0}^{1}\tau^{\alpha-1} \,dK(\tau) \biggr) \biggl( \int_{0}^{1} k_{2}(\tau) \,dH(\tau) \biggr)>0. $$

(d₁):

\(G_{4}(t,s)\le\sigma_{4} h_{1}(s)\), \(\forall(t,s)\in[0,1]\times [0,1]\), where \(\sigma_{4}=\frac{1}{\Delta}(K(1)-K(0))>0\).

(d₂):

\(G_{4}(t,s)\le\delta_{4} t^{\beta-1}\), \(\forall(t,s)\in[0,1]\times [0,1]\), where \(\delta_{4}=\frac{1}{\Delta\Gamma(\alpha-1)}\int_{0}^{1}(1-\tau )\tau^{\alpha-1} \,dK(\tau)>0\).

(d₃):

\(G_{4}(t,s)\ge\varrho_{4} t^{\beta-1} h_{1}(s)\), \(\forall(t,s)\in [0,1]\times[0,1]\), where \(\varrho_{4}=\frac{1}{\Delta}\int_{0}^{1} k_{1}(\tau) \,dK(\tau)>0\).

Proof

From the assumptions of this lemma, we obtain

By using Lemma 2.2, we deduce, for all \((t,s)\in[0,1]\times[0,1]\):

(a₁)

(a₂)

(a₃)

(b₁)

(b₂)

(b₃)

(c₁)

(c₂)

(c₃)

(d₁)

(d₂)

(d₃)

 □

Lemma 2.5

Assume that \(H, K:[0,1]\to\mathbb{R}\) are nondecreasing functions, \(\Delta>0\), \(\int_{0}^{1}\tau^{\alpha-1}(1-\tau) \,dK(\tau)>0\), \(\int_{0}^{1}\tau^{\beta-1}(1-\tau) \,dH(\tau)>0\), and \(\tilde{x}, \tilde{y}\in C(0,1)\cap L^{1}(0,1)\), \(\tilde{x}(t)\ge0\), \(\tilde{y}(t)\ge0\) for all \(t\in(0,1)\). Then the solution \((u,v)\) of problem (1)-(2) given by (3) satisfies the inequalities \(u(t)\ge\gamma_{1} t^{\alpha-1}u(t')\), \(v(t)\ge\gamma_{2} t^{\beta-1} v(t')\), for all \(t, t'\in[0,1]\), where \(\gamma_{1}=\min \{\frac{\varrho_{1}}{\sigma_{1}},\frac{\varrho _{2}}{\sigma_{2}} \}>0\), \(\gamma_{2}=\min \{\frac{\varrho_{3}}{\sigma _{3}},\frac{\varrho_{4}}{\sigma_{4}} \}>0\).

Proof

By using Lemma 2.4, we obtain

In a similar way, we deduce

 □

In the proof of our main results we shall use the nonlinear alternative of Leray-Schauder type and the Guo-Krasnosel’skii fixed point theorem presented below (see [14, 15]).

Theorem 2.1

Let X be a Banach space with \(\Omega\subset X\) closed and convex. Assume U is a relatively open subset of Ω with \(0\in U\), and let \(S:\bar{U}\to\Omega\) be a completely continuous operator (continuous and compact). Then either

1. (1)

   S has a fixed point in Ū, or

2. (2)

   there exist \(u\in\partial U\) and \(\nu\in(0,1)\) such that \(u=\nu Su\).

Theorem 2.2

Let X be a Banach space and let \(C\subset X\) be a cone in X. Assume \(\Omega_{1}\) and \(\Omega_{2}\) are bounded open subsets of X with \(0\in \Omega_{1}\subset\bar{\Omega}_{1}\subset\Omega_{2}\) and let \({\mathcal {A}}:C\cap(\bar{\Omega}_{2}\setminus\Omega_{1})\to C\) be a completely continuous operator such that either

1. (i)

   \(\|{\mathcal{A}} u\|\le\|u\|\), \(u\in C\cap\partial \Omega_{1}\), and \(\|{\mathcal{A}} u\|\ge\|u\|\), \(u\in C\cap\partial\Omega_{2}\), or

2. (ii)

   \(\|{\mathcal{A}} u\|\ge\|u\|\), \(u\in C\cap\partial \Omega_{1}\), and \(\|{\mathcal{A}} u\|\le\|u\|\), \(u\in C\cap\partial \Omega_{2}\).

Then \({\mathcal{A}}\) has a fixed point in \(C\cap(\bar{\Omega} _{2}\setminus\Omega_{1})\).

In this section, we investigate the existence and multiplicity of positive solutions for our problem (S)-(BC). We present now the assumptions that we shall use in the sequel.

(H1):

\(H, K:[0,1]\to\mathbb{R}\) are nondecreasing functions, \(\Delta=1- (\int_{0}^{1}\tau^{\alpha-1} \,dK(\tau) )\times (\int _{0}^{1}\tau^{\beta-1} \,dH(\tau) ) >0\), and \(\int_{0}^{1}\tau^{\alpha-1}(1-\tau) \,dK(\tau)>0\), \(\int_{0}^{1}\tau^{\beta -1}(1-\tau) \,dH(\tau)>0\).

(H2):

The functions \(f, g\in C([0,1]\times[0,\infty)\times [0,\infty), (-\infty,+\infty))\) and there exist functions \(p_{1}, p_{2}\in C([0,1],[0,\infty))\) such that \(f(t,u,v)\ge-p_{1}(t)\) and \(g(t,u,v)\ge -p_{2}(t)\) for any \(t\in[0,1]\) and \(u, v\in[0,\infty)\).

(H3):

\(f(t,0,0)>0\), \(g(t,0,0)>0\) for all \(t\in[0,1]\).

(H4):

The functions \(f, g\in C((0,1)\times[0,\infty)\times [0,\infty),(-\infty,+\infty))\), f, g may be singular at \(t=0\) and/or \(t=1\), and there exist functions \(p_{1}, p_{2}\in C((0,1),[0,\infty))\), \(\alpha_{1}, \alpha_{2}\in C((0,1),[0,\infty))\), \(\beta_{1}, \beta_{2}\in C([0,1]\times[0,\infty)\times[0,\infty),[0,\infty ))\) such that

$$-p_{1}(t)\le f(t,u,v)\le\alpha_{1}(t)\beta_{1}(t,u,v), \qquad -p_{2}(t)\le g(t,u,v)\le\alpha_{2}(t) \beta_{2}(t,u,v), $$

for all \(t\in(0,1)\), \(u, v\in[0,\infty)\), with \(0<\int_{0}^{1} p_{i}(s) \,ds<\infty\), \(0<\int_{0}^{1}\alpha_{i}(s) \,ds<\infty\), \(i=1,2\).

(H5):

There exists \(c\in(0,1/2)\) such that

$$f_{\infty}= \lim_{u+v\to\infty} \min_{t\in[c,1-c]} \frac {f(t,u,v)}{u+v}=\infty \quad \mbox{or}\quad g_{\infty}= \lim _{u+v\to\infty} \min_{t\in[c,1-c]} \frac {g(t,u,v)}{u+v}=\infty. $$

(H6):

\(\beta_{i\infty}= \lim_{u+v\to\infty} \max_{t\in[0,1]} \frac{\beta_{i}(t,u,v)}{u+v}=0\), \(i=1,2\).

We consider the system of nonlinear fractional differential equations

with the integral boundary conditions

where \(z(t)^{*}=z(t)\) if \(z(t)\ge0\), and \(z(t)^{*}=0\) if \(z(t)<0\). Here \((q_{1},q_{2})\) with

is solution of the system of fractional differential equations

with the integral boundary conditions

Under the assumptions (H1) and (H2), or (H1) and (H4), we have \(q_{1}(t)\ge0\), \(q_{2}(t)\ge0\) for all \(t\in[0,1]\).

We shall prove that there exists a solution \((x,y)\) for the boundary value problem (6)-(7) with \(x(t)\ge q_{1}(t)\) and \(y(t)\ge q_{2}(t)\) on \([0,1]\), \(x(t)>q_{1}(t)\), \(y(t)>q_{2}(t)\) on \((0,1)\). In this case \((u,v)\) with \(u(t)=x(t)-q_{1}(t)\) and \(v(t)=y(t)-q_{2}(t)\), \(t\in[0,1]\) represents a positive solution of boundary value problem (S)-(BC).

By using Lemma 2.1 (relations (3)), a solution of the system

is a solution for problem (6)-(7).

We consider the Banach space \(X=C([0,1])\) with the supremum norm \(\| \cdot\|\), and the Banach space \(Y=X\times X\) with the norm \(\|(u,v)\| _{Y}=\|u\|+\|v\|\). We define the cones

where \(\gamma_{1}\), \(\gamma_{2}\) are defined in Section 2 (Lemma 2.5), and \(P=P_{1}\times P_{2}\subset Y\).

For \(\lambda, \mu>0\), we introduce the operators \(Q_{1}, Q_{2}:Y\to X\) and \({\mathcal{Q}}:Y\to Y\) defined by \({\mathcal {Q}}(x,y)=(Q_{1}(x,y),Q_{2}(x,y))\), \((x,y)\in Y\) with

It is clear that if \((x,y)\) is a fixed point of operator \({\mathcal {Q}}\), then \((x,y)\) is a solution of problem (6)-(7).

Lemma 3.1

If (H1) and (H2), or (H1) and (H4) hold, then operator \({\mathcal{Q}}:P\to P\) is a completely continuous operator.

Proof

The operators \(Q_{1}\) and \(Q_{2}\) are well defined. To prove this, let \((x,y)\in P\) be fixed with \(\|(x,y)\|_{Y}=\widetilde{L}\). Then we have

If (H1) and (H2) hold, then we deduce easily that \(Q_{1}(x,y)(t)< \infty\) and \(Q_{2}(x,y)(t)< \infty\) for all \(t\in[0,1]\).

If (H1) and (H4) hold, we deduce, for all \(t\in[0,1]\),

where \(M=\max \{ \max_{t\in[0,1], u,v\in[0,\widetilde{L}]}\beta _{1}(t,u,v), \max_{t\in[0,1], u,v\in[0,\widetilde{L}]}\beta _{2}(t,u,v),1 \}\).

Besides, by Lemma 2.5, we conclude that

and so \(Q_{1}(x,y), Q_{2}(x,y)\in P\).

By using standard arguments, we deduce that operator \({\mathcal {Q}}:P\to P\) is a completely continuous operator (a compact operator, that is, one that maps bounded sets into relatively compact sets and is continuous). □

Theorem 3.1

Assume that (H1)-(H3) hold. Then there exist constants \(\lambda_{0}>0\) and \(\mu_{0}>0\) such that, for any \(\lambda\in(0,\lambda_{0}]\) and \(\mu\in(0,\mu_{0}]\), the boundary value problem (S)-(BC) has at least one positive solution.

Proof

Let \(\delta\in(0,1)\) be fixed. From (H2) and (H3), there exists \(R_{0}\in(0,1]\) such that

We define

We will show that, for any \(\lambda\in(0,\lambda_{0}]\) and \(\mu\in(0,\mu _{0}]\), problem (6)-(7) has at least one positive solution.

So, let \(\lambda\in(0,\lambda_{0}]\) and \(\mu\in(0,\mu_{0}]\) be arbitrary, but fixed for the moment. We define the set \(U=\{(x,y)\in P, \|(u,v)\| _{Y}< R_{0}\}\). We suppose that there exist \((x,y)\in\partial U\) (\(\|(x,y)\| _{Y}=R_{0}\) or \(\|x\|+\|y\|=R_{0}\)) and \(\nu\in(0,1)\) such that \((x,y)=\nu{\mathcal{Q}}(x,y)\) or \(x=\nu Q_{1}(x,y)\), \(y=\nu Q_{2}(x,y)\).

We deduce that

Then by Lemma 2.4, for all \(t\in[0,1]\), we obtain

Hence \(\|x\|\le\frac{R_{0}}{4}\) and \(\|y\|\le\frac{R_{0}}{4}\). Then \(R_{0}=\| (x,y)\|_{Y}=\|x\|+\|y\|\le\frac{R_{0}}{4}+\frac{R_{0}}{4}=\frac{R_{0}}{2}\), which is a contradiction.

Therefore, by Theorem 2.1 (with \(\Omega=P\)), we deduce that \({\mathcal{Q}}\) has a fixed point \((x_{0},y_{0})\in\bar{U}\cap P\). That is, \((x_{0},y_{0})={\mathcal{Q}}(x_{0},y_{0})\) or \(x_{0}=Q_{1}(x_{0},y_{0})\), \(y_{0}=Q_{2}(x_{0},y_{0})\), and \(\|x_{0}\|+\|y_{0}\|\le R_{0}\) with \(x_{0}(t)\ge\gamma _{1} t^{\alpha-1}\|x_{0}\|\) and \(y_{0}(t)\ge\gamma_{2} t^{\beta-1}\|y_{0}\|\) for all \(t\in[0,1]\).

Moreover, by (10), we conclude

Therefore \(x_{0}(t)\ge q_{1}(t)\), \(y_{0}(t)\ge q_{2}(t)\) for all \(t\in[0,1]\), and \(x_{0}(t)>q_{1}(t)\), \(y_{0}(t)>q_{2}(t)\) for all \(t\in(0,1)\). Let \(u_{0}(t)=x_{0}(t)-q_{1}(t)\) and \(v_{0}(t)=y_{0}(t)-q_{2}(t)\) for all \(t\in[0,1]\). Then \(u_{0}(t)\ge0\), \(v_{0}(t)\ge0\) for all \(t\in[0,1]\), \(u_{0}(t)>0\), \(v_{0}(t)>0\) for all \(t\in(0,1)\). Therefore \((u_{0},v_{0})\) is a positive solution of (S)-(BC). □

Theorem 3.2

Assume that (H1), (H4), and (H5) hold. Then there exist \(\lambda^{*}>0\) and \(\mu^{*}>0\) such that, for any \(\lambda\in(0,\lambda^{*}]\) and \(\mu\in(0,\mu^{*}]\), the boundary value problem (S)-(BC) has at least one positive solution.

Proof

We choose a positive number

and we define the set \(\Omega_{1}=\{(x,y)\in P, \|(x,y)\|_{Y}< R_{1}\}\).

We introduce

with

Let \(\lambda\in(0,\lambda^{*}]\) and \(\mu\in(0,\mu^{*}]\). Then, for any \((x,y)\in P\cap\partial\Omega_{1}\) and \(s\in[0,1]\), we have

Then, for any \((x,y)\in P\cap\partial\Omega_{1}\), we obtain

Therefore

On the other hand, we choose a constant \(L>0\) such that

From (H5), we deduce that there exists a constant \(M_{0}>0\) such that

Now we define

and let \(\Omega_{2}=\{(x,y)\in P, \|(x,y)\|_{Y}< R_{2}\}\).

We suppose that \(f_{\infty}=\infty\), that is, \(f(t,u,v)\ge L(u+v)\) for all \(t\in[c,1-c]\) and \(u,v\ge0\), \(u+v\ge M_{0}\). Then, for any \((x,y)\in P\cap\partial\Omega_{2}\), we have \(\|(x,y)\| _{Y}=R_{2}\) or \(\|x\|+\|y\|=R_{2}\). We deduce that \(\|x\|\ge\frac{R_{2}}{2}\) or \(\|y\|\ge\frac{R_{2}}{2}\).

We suppose that \(\|x\|\ge\frac{R_{2}}{2}\). Then, for any \((x,y)\in P\cap \partial\Omega_{2}\), we obtain

Therefore, we conclude

Hence

Then, for any \((x,y)\in P\cap\partial\Omega_{2}\) and \(t\in[c,1-c]\), by (12) and (13), we deduce

It follows that, for any \((x,y)\in P\cap\partial\Omega_{2}\), \(t\in [c,1-c]\), we obtain

Then \(\|Q_{1}(x,y)\|\ge\|(x,y)\|_{Y}\) and

If \(\|y\|\ge\frac{R_{2}}{2}\), then by a similar approach, we obtain again relation (14).

We suppose now that \(g_{\infty}=\infty\), that is, \(g(t,u,v)\ge L(u+v)\), for all \(t\in[c,1-c]\) and \(u,v\ge0\), \(u+v\ge M_{0}\). Then, for any \((x,y)\in P\cap\partial\Omega_{2}\), we have \(\|(x,y)\|_{Y}=R_{2}\). Hence \(\| x\|\ge\frac{R_{2}}{2}\) or \(\|y\|\ge\frac{R_{2}}{2}\).

If \(\|x\|\ge\frac{R_{2}}{2}\), then for any \((x,y)\in P\cap\partial \Omega_{2}\) we deduce in a similar manner as above that \(x(t)-q_{1}(t)\ge \frac{1}{2}x(t)\) for all \(t\in[0,1]\) and

Hence we obtain relation (14).

If \(\|y\|\ge\frac{R_{2}}{2}\), then in a similar way as above, we deduce again relation (14).

Therefore, by Theorem 2.2, relations (11) and (14), we conclude that \({\mathcal{Q}}\) has a fixed point \((x_{1},y_{1}) \in P\cap(\bar{\Omega}_{2}\setminus\Omega_{1})\), that is, \(R_{1}\le\| (x_{1},y_{1})\|_{Y}\le R_{2}\). Since \(\|(x_{1},y_{1})\|_{Y}\ge R_{1}\), then \(\|x_{1}\|\ge \frac{R_{1}}{2}\) or \(\|y_{1}\|\ge\frac{R_{1}}{2}\).

We suppose first that \(\|x_{1}\|\ge\frac{R_{1}}{2}\). Then we deduce

and so \(x_{1}(t)\ge q_{1}(t)+\Lambda_{1} t^{\alpha-1}\) for all \(t\in[0,1]\), where \(\Lambda_{1}=\frac{\gamma_{1} R_{1}}{2}-\int_{0}^{1}(\delta_{1} p_{1}(s)+\delta _{2} p_{2}(s)) \,ds>0\).

Then \(y_{1}(1)=\int_{0}^{1}x_{1}(s) \,dK(s)\ge\Lambda_{1}\int_{0}^{1}s^{\alpha-1} \,dK(s)>0\) and

Therefore, we obtain

where \(\Lambda_{2}=\frac{\gamma_{1}\gamma_{2} R_{1}}{2}\int_{0}^{1}s^{\alpha -1}\,dK(s)-\int_{0}^{1}(\delta_{3} p_{2}(s)+\delta_{4} p_{1}(s)) \,ds>0\).

Hence \(y_{1}(t)\ge q_{2}(t)+\Lambda_{2} t^{\beta-1}\) for all \(t\in[0,1]\).

If \(\|y_{1}\|\ge\frac{R_{1}}{2}\), then by a similar approach, we deduce that \(y_{1}(t)\ge q_{2}(t)+\Lambda_{3} t^{\beta-1}\) and \(x_{1}(t)\ge q_{1}(t)+\Lambda_{4} t^{\alpha-1}\) for all \(t\in[0,1]\), where \(\Lambda_{3}=\frac{\gamma_{2} R_{1}}{2}-\int_{0}^{1}(\delta_{3} p_{2}(s)+\delta _{4} p_{1}(s)) \,ds>0\) and \(\Lambda_{4}=\frac{\gamma_{1}\gamma_{2} R_{1}}{2}\int_{0}^{1}s^{\beta-1}\,dH(s)-\int _{0}^{1}(\delta_{1} p_{1}(s)+\delta_{2} p_{2}(s)) \,ds>0\).

Let \(u_{1}(t)=x_{1}(t)-q_{1}(t)\) and \(v_{1}(t)=y_{1}(t)-q_{2}(t)\) for all \(t\in [0,1]\). Then \((u_{1},v_{1})\) is a positive solution of (S)-(BC) with \(u_{1}(t)\ge\Lambda_{5} t^{\alpha-1}\) and \(v_{1}(t)\ge\Lambda_{6} t^{\beta -1}\) for all \(t\in[0,1]\), where \(\Lambda_{5}=\min\{\Lambda_{1},\Lambda_{4}\} \) and \(\Lambda_{6}=\min\{\Lambda_{2},\Lambda_{3}\}\). This completes the proof of Theorem 3.2. □

Theorem 3.3

Assume that (H1), (H3), (H5), and

(H4′):

The functions \(f, g\in C([0,1]\times[0,\infty)\times [0,\infty),(-\infty,+\infty))\) and there exist functions \(p_{1}, p_{2}, \alpha_{1}, \alpha_{2}\in C([0,1],[0,\infty))\), \(\beta_{1}, \beta _{2}\in C([0,1]\times[0,\infty)\times[0,\infty),[0,\infty))\) such that

$$-p_{1}(t)\le f(t,u,v)\le\alpha_{1}(t)\beta_{1}(t,u,v), \qquad -p_{2}(t)\le g(t,u,v)\le\alpha_{2}(t) \beta_{2}(t,u,v), $$

for all \(t\in[0,1]\), \(u, v\in[0,\infty)\), with \(\int_{0}^{1} p_{i}(s) \,ds>0\), \(i=1,2\),

hold. Then the boundary value problem (S)-(BC) has at least two positive solutions for \(\lambda>0\) and \(\mu>0\) sufficiently small.

Proof

Because assumption (H4′) implies assumptions (H2) and (H4), we can apply Theorems 3.1 and 3.2. Therefore, we deduce that, for \(0<\lambda\le\min\{\lambda_{0},\lambda^{*}\} \) and \(0<\mu\le\min\{\mu_{0},\mu^{*}\}\), problem (S)-(BC) has at least two positive solutions \((u_{0},v_{0})\) and \((u_{1},v_{1})\) with \(\|(u_{0}+q_{1},v_{0}+q_{2})\|_{Y}\le1\) and \(\| (u_{1}+q_{1},v_{1}+q_{2})\|_{Y} >1\). □

Theorem 3.4

Assume that \(\lambda=\mu\), and (H1), (H4), and (H6) hold. In addition if

(H7):

there exists \(c\in(0,1/2)\) such that

$$f_{\infty}^{i}= \liminf_{\substack{u+v\to\infty\\u,v\ge0}} \min _{t\in [c,1-c]}f(t,u,v)>L_{0} \quad \textit{or}\quad g_{\infty}^{i}= \liminf_{\substack{u+v\to\infty\\u,v\ge0}} \min _{t\in [c,1-c]}g(t,u,v)>L_{0}, $$

where

$$\begin{aligned} L_{0} =&\max\biggl\{ \frac{4}{\gamma_{1}} \int_{0}^{1}\bigl(\delta_{1} p_{1}(s)+\delta_{2} p_{2}(s)\bigr)\,ds, \frac{4}{\gamma_{2}} \int_{0}^{1}\bigl(\delta_{3} p_{2}(s)+\delta_{4} p_{1}(s)\bigr)\,ds, \\ &\frac{4}{\gamma_{1}\gamma_{2}} \biggl( \int_{0}^{1} s^{\alpha-1}\,dK(s) \biggr)^{-1} \int_{0}^{1}\bigl(\delta_{3} p_{2}(s)+\delta_{4} p_{1}(s)\bigr)\,ds, \\ &\frac{4}{\gamma_{1}\gamma_{2}} \biggl( \int_{0}^{1} s^{\beta-1}\,dH(s) \biggr)^{-1} \int_{0}^{1}\bigl(\delta_{1} p_{1}(s)+\delta_{2} p_{2}(s)\bigr)\,ds\biggr\} \\ &{}\times \biggl(\min \biggl\{ c^{\alpha-1}\varrho_{1} \int_{c}^{1-c}h_{1}(s) \,ds,c^{\alpha-1}\varrho_{2} \int_{c}^{1-c}h_{2}(s) \,ds \biggr\} \biggr)^{-1}, \end{aligned}$$

then there exists \(\lambda_{*}>0\) such that for any \(\lambda\ge\lambda _{*}\) problem (S)-(BC) (with \(\lambda=\mu\)) has at least one positive solution.

Proof

By (H7) we conclude that there exists \(M_{3}>0\) such that

We define

We assume now \(\lambda\ge\lambda_{*}\). Let

and \(\Omega_{3}=\{(x,y)\in P, \|(x,y)\|_{Y}< R_{3}\}\).

We suppose first that \(f_{\infty}^{i}>L_{0}\), that is, \(f(t,u,v)\ge L_{0}\) for all \(t\in[c,1-c]\) and \(u,v\ge0\), \(u+v\ge M_{3}\). Let \((x,y)\in P\cap \partial\Omega_{3}\). Then \(\|(x,y)\|_{Y}=R_{3}\), so \(\|x\|\ge R_{3}/2\) or \(\| y\|\ge R_{3}/2\). We assume that \(\|x\|\ge R_{3}/2\). Then for all \(t\in[0,1]\) we deduce

Therefore, for any \((x,y)\in P\cap\partial\Omega_{3}\) and \(t\in [c,1-c]\), we have

Hence, for any \((x,y)\in P\cap\partial\Omega_{3}\) and \(t\in[c,1-c]\), we conclude

Therefore we obtain \(\|Q_{1}(x,y)\|\ge R_{3}\) for all \((x,y)\in P\cap \partial\Omega_{3}\), and so

If \(\|y\|\ge R_{3}/2\), then by a similar approach we deduce again relation (16).

We suppose now that \(g_{\infty}^{i}>L_{0}\), that is, \(g(t,u,v)\ge L_{0}\) for all \(t\in[c,1-c]\) and \(u,v\ge0\), \(u+v\ge M_{3}\). Let \((x,y)\in P\cap \partial\Omega_{3}\). Then \(\|(x,y)\|_{Y}=R_{3}\), so \(\|x\|\ge R_{3}/2\) or \(\| y\|\ge R_{3}/2\). If \(\|x\|\ge R_{3}/2\), then we obtain in a similar manner as in the first case above (\(f_{\infty}^{i}>L_{0}\)) that \(x(t)-q_{1}(t)\ge\frac {M_{3}}{c^{\alpha-1}}t^{\alpha-1}\ge0\) for all \(t\in[0,1]\).

Therefore, for any \((x,y)\in P\cap\partial\Omega_{3}\) and \(t\in [c,1-c]\), we deduce inequalities (15).

Hence, for any \((x,y)\in P\cap\partial\Omega_{3}\) and \(t\in[c,1-c]\), we conclude

Therefore we obtain \(\|Q_{1}(x,y)\|\ge R_{3}\), and so \(\|{\mathcal {Q}}(x,y)\|_{Y}\ge R_{3}=\|(x,y)\|_{Y}\) for all \((x,y)\in P\cap\partial\Omega _{3}\), that is, we have relation (16).

By a similar approach we obtain relation (16) if \(\|y\|\ge R_{3}/2\).

On the other hand, we consider the positive number

Then by (H6) we deduce that there exists \(M_{4}>0\) such that

Therefore we obtain

where \(M_{5}= \max_{i=1,2} \{ \max_{t\in[0,1], u,v\ge0, u+v\le M_{4}}\beta_{i}(t,u,v) \}\).

We define now

and let \(\Omega_{4}=\{(x,y)\in P, \|(x,y)\|_{Y}< R_{4}\}\).

For any \((x,y)\in P\cap\partial\Omega_{4}\), we have

and so \(\|Q_{1}(x,y)\|\le\frac{\|(x,y)\|_{Y}}{2}\) for all \((x,y)\in P\cap \partial\Omega_{4}\).

In a similar way we obtain \(Q_{2}(x,y)(t)\le\frac{\|(x,y)\|_{Y}}{2}\) for all \(t\in[0,1]\), and so \(\|Q_{2}(x,y)\|\le\frac{\|(x,y)\|_{Y}}{2}\) for all \((x,y)\in P\cap\partial\Omega_{4}\).

Therefore, we deduce

By Theorem 2.2, (16), and (17), we conclude that \({\mathcal{Q}}\) has a fixed point \((x_{1},y_{1})\in P\cap(\bar{\Omega}_{4}\setminus\Omega_{3})\). Since \(\|(x_{1},y_{1})\|\ge R_{3}\) then \(\|x_{1}\| \ge R_{3}/2\) or \(\|y_{1}\|\ge R_{3}/2\).

We suppose that \(\|x_{1}\|\ge R_{3}/2\). Then \(x_{1}(t)-q_{1}(t)\ge\frac {M_{3}}{c^{\alpha-1}}t^{\alpha-1}\) for all \(t\in[0,1]\). Besides

and then

Therefore, we deduce that, for all \(t\in[0,1]\),

If \(\|y_{1}\|\ge R_{3}/2\), then by a similar approach we conclude again that \(x_{1}(t)-q_{1}(t)\ge\frac{M_{3}}{c^{\alpha-1}}t^{\alpha-1}\) and \(y_{1}(t)-q_{2}(t)\ge\frac{M_{3}}{c^{\beta-1}}t^{\beta-1}\) for all \(t\in[0,1]\).

Let \(u_{1}(t)=x_{1}(t)-q_{1}(t)\) and \(v_{1}(t)=y_{1}(t)-q_{2}(t)\) for all \(t\in [0,1]\). Then \(u_{1}(t)\ge\widetilde{\Lambda}_{1} t^{\alpha-1}\) and \(v_{1}(t)\ge\widetilde{\Lambda}_{2} t^{\beta-1}\) for all \(t\in[0,1]\), where \(\widetilde{\Lambda}_{1}=\frac{M_{3}}{c^{\alpha-1}}\), \(\widetilde{\Lambda}_{2}=\frac{M_{3}}{c^{\beta-1}}\). Hence we deduce that \((u_{1},v_{1})\) is a positive solution of (S)-(BC), which completes the proof of Theorem 3.4. □

In a similar manner as we proved Theorem 3.4, we obtain the following theorems.

Theorem 3.5

Assume that \(\lambda=\mu\), and (H1), (H4), and (H6) hold. In addition if

(H7′):

there exists \(c\in(0,1/2)\) such that

$$f_{\infty}^{i}= \liminf_{\substack{u+v\to\infty\\u,v\ge0}} \min _{t\in [c,1-c]}f(t,u,v)>\widetilde{L}_{0} \quad \textit{or} \quad g_{\infty}^{i}= \liminf_{\substack{u+v\to\infty\\u,v\ge0}} \min _{t\in [c,1-c]}g(t,u,v)>\widetilde{L}_{0}, $$

where

$$\begin{aligned} \widetilde{L}_{0} =&\max\biggl\{ \frac{4}{\gamma_{1}} \int_{0}^{1}\bigl(\delta_{1} p_{1}(s)+\delta_{2} p_{2}(s)\bigr)\,ds, \frac{4}{\gamma_{2}} \int_{0}^{1}\bigl(\delta_{3} p_{2}(s)+\delta_{4} p_{1}(s)\bigr)\,ds, \\ &\frac{4}{\gamma_{1}\gamma_{2}} \biggl( \int_{0}^{1} s^{\alpha-1}\,dK(s) \biggr)^{-1} \int_{0}^{1}\bigl(\delta_{3} p_{2}(s)+\delta_{4} p_{1}(s)\bigr)\,ds, \\ &\frac{4}{\gamma_{1}\gamma_{2}} \biggl( \int_{0}^{1} s^{\beta-1}\,dH(s) \biggr)^{-1} \int_{0}^{1}\bigl(\delta_{1} p_{1}(s)+\delta_{2} p_{2}(s)\bigr)\,ds\biggr\} \\ &{}\times \biggl(\min \biggl\{ c^{\beta-1}\varrho_{3} \int_{c}^{1-c}h_{2}(s) \,ds,c^{\beta-1}\varrho_{4} \int_{c}^{1-c}h_{1}(s) \,ds \biggr\} \biggr)^{-1}, \end{aligned}$$

then there exists \(\lambda'_{*}>0\) such that for any \(\lambda\ge\lambda '_{*}\) problem (S)-(BC) (with \(\lambda=\mu\)) has at least one positive solution.

Theorem 3.6

Assume that \(\lambda=\mu\), and (H1), (H4), and (H6) hold. In addition if

(H8):

there exists \(c\in(0,1/2)\) such that

$$\hat{f}_{\infty}= \lim_{\substack{u+v\to\infty\\u,v\ge0}} \min_{t\in [c,1-c]}f(t,u,v)= \infty \quad \textit{or}\quad \hat{g}_{\infty}= \lim_{\substack{u+v\to\infty\\u,v\ge0}} \min_{t\in [c,1-c]}g(t,u,v)=\infty, $$

then there exists \(\tilde{\lambda}_{*}>0\) such that for any \(\lambda \ge\tilde{\lambda}_{*}\) problem (S)-(BC) (with \(\lambda=\mu\)) has at least one positive solution.

Let \(\alpha=5/2\) (\(n=3\)), \(\beta=7/3\) (\(m=3\)), \(H(t)=t^{2}\), \(K(t)=t^{3}\). Then \(\int_{0}^{1}u(s)\,dK(s)=3\int_{0}^{1}s^{2}u(s) \,ds\) and \(\int _{0}^{1}v(s)\,dH(s)=2\int_{0}^{1}sv(s) \,ds\).

We consider the system of fractional differential equations

with the boundary conditions

Then we obtain \(\Delta=1- (\int_{0}^{1}s^{\alpha-1}\,dK(s) ) (\int_{0}^{1}s^{\beta-1}\,dH(s) )=\frac{3}{5}>0\), \(\int_{0}^{1}\tau^{\alpha -1}(1-\tau) \,dK(\tau)=\frac{4}{33}>0\), \(\int_{0}^{1}\tau^{\beta-1}(1-\tau )\,dH(\tau)=\frac{9}{65}>0\). The functions H and K are nondecreasing, and so assumption (H1) is satisfied. Besides, we deduce

We also obtain \(h_{1}(s)=\frac{2}{\sqrt{\pi}}s(1-s)^{3/2}\), \(h_{2}(s)=\frac {1}{\Gamma(4/3)}s(1-s)^{4/3}\),

In addition, we have \(\sigma_{1}=2\), \(\delta_{1}=\frac{74}{33\sqrt{\pi}}\), \(\varrho_{1}=\frac{8\sqrt{2}-1}{63\sqrt{2}}\), \(\sigma_{2}=\frac{5}{3}\), \(\delta_{2}=\frac{3}{13\Gamma(4/3)}\), \(\varrho_{2}=\frac{36\sqrt [3]{2}-9}{112\sqrt[3]{2}}\), \(\sigma_{3}=\frac{19}{9}\), \(\delta_{3}=\frac{15}{13\Gamma(4/3)}\), \(\varrho _{3}=\frac{12\sqrt[3]{2}-3}{56\sqrt[3]{2}}\), \(\sigma_{4}=\frac{5}{3}\), \(\delta_{4}=\frac{40}{99\sqrt{\pi}}\), \(\varrho_{4}=\frac{40\sqrt {2}-5}{189\sqrt{2}}\), \(\gamma_{1}=\frac{8\sqrt{2}-1}{126\sqrt{2}}\approx 0.0578801\), \(\gamma_{2}=\frac{9(12\sqrt[3]{2}-3)}{1064\sqrt[3]{2}}\approx0.08136286\).

Example 1

We consider the functions

We have \(p_{1}(t)=-\ln t\), \(p_{2}(t)=-\ln(1-t)\), \(\alpha_{1}(t)=\alpha _{2}(t)=\frac{1}{\sqrt{t(1-t)}}\) for all \(t\in(0,1)\), \(\beta _{1}(t,u,v)=(u+v)^{2}\), \(\beta_{2}(t,u,v)=2+\sin(u+v)\) for all \(t\in[0,1]\), \(u, v\ge0\), \(\int_{0}^{1}p_{1}(t) \, dt=1\), \(\int_{0}^{1}p_{2}(t)\, dt=1\), \(\int_{0}^{1}\alpha_{i}(t)\, dt=\pi\), \(i=1,2\). Therefore, assumption (H4) is satisfied. In addition, for \(c\in(0,1/2)\) fixed, assumption (H5) is also satisfied (\(f_{\infty}=\infty\)).

After some computations, we deduce \(\int_{0}^{1}(\delta_{1}p_{1}(s)+\delta _{2}p_{2}(s)) \,ds\approx1.52357852\), \(\int_{0}^{1}(\delta_{3} p_{2}(s)+\delta_{4} p_{1}(s)) \,ds\approx1.520086\), \(\int_{0}^{1}h_{1}(s)(\alpha_{1}(s)+p_{1}(s)) \,ds\approx0.42548534\), \(\int_{0}^{1}h_{2}(s)(\alpha_{2}(s)+p_{2}(s)) \,ds\approx 0.44092924\). We choose \(R_{1}=1080\), which satisfies the condition from the beginning of the proof of Theorem 3.2. Then \(M_{1}=R_{1}^{2}\), \(M_{2}=3\), \(\lambda^{*}\approx2.7202\cdot10^{-4}\), and \(\mu^{*}=1\). By Theorem 3.2, we conclude that (\(\mathrm{S}_{0}\))-(\(\mathrm{BC}_{0}\)) has at least one positive solution for any \(\lambda\in(0,\lambda^{*}]\) and \(\mu \in(0,\mu^{*}]\).

Example 2

We consider the functions

We have \(p_{1}(t)=p_{2}(t)=1\) for all \(t\in[0,1]\), and then assumption (H2) is satisfied. Besides, assumption (H3) is also satisfied, because \(f(t,0,0)=1\) and \(g(t,0,0)=1\) for all \(t\in[0,1]\).

Let \(\delta=\frac{1}{2}<1\) and \(R_{0}=1\). Then

In addition,

We also obtain \(c_{1}\approx0.25791523\), \(c_{2}\approx0.23996711\), \(c_{3}\approx0.30395834\), \(c_{4}\approx0.21492936\), and then \(\lambda _{0}=\max \{\frac{R_{0}}{8c_{1}\bar{f}(R_{0})},\frac{R_{0}}{8c_{4}\bar{f}(R_{0})} \}\approx0.10497377\) and \(\mu_{0}=\max \{\frac{R_{0}}{8c_{2}\bar{g}(R_{0})},\frac{R_{0}}{8c_{3}\bar{g}(R_{0})} \}\approx 0.1677744\).

By Theorem 3.1, for any \(\lambda\in(0,\lambda_{0}]\) and \(\mu \in(0,\mu_{0}]\), we deduce that problem (\(\mathrm{S}_{0}\))-(\(\mathrm{BC}_{0}\)) has at least one positive solution.

Because assumption (H4′) is satisfied (\(\alpha_{1}(t)=\alpha_{2}(t)=1\), \(\beta_{1}(t,u,v)=(u+v)^{2}+1\), \(\beta_{2}(t,u,v)=(u+v)^{1/2}+1\) for all \(t\in[0,1]\), \(u,v\ge0\)) and assumption (H5) is also satisfied (\(f_{\infty}=\infty\)), by Theorem 3.3 we conclude that problem (\(\mathrm{S}_{0}\))-(\(\mathrm{BC}_{0}\)) has at least two positive solutions for λ and μ sufficiently small.

Example 3

We consider \(\lambda=\mu\) and the functions

where \(a\in(0,1)\).

Here we have \(p_{1}(t)=\frac{1}{\sqrt{t}}\), \(p_{2}(t)=\frac{1}{\sqrt {1-t}}\), \(\alpha_{1}(t)=\frac{1}{\sqrt[3]{t^{2}(1-t)}}\), \(\alpha_{2}(t)=\frac {1}{\sqrt[3]{t(1-t)^{2}}}\) for all \(t\in(0,1)\), \(\beta_{1}(t,u,v)=(u+v)^{a}\), \(\beta_{2}(t,u,v)=\ln(1+u+v)\) for all \(t\in[0,1]\), \(u,v\ge0\). For \(c\in (0,1/2)\) fixed, the assumptions (H4), (H6), and (H8) are satisfied (\(\beta_{i\infty }=0\) for \(i=1,2\) and \(\hat{f}_{\infty}=\infty\)).

Then by Theorem 3.6, we deduce that there exists \(\tilde {\lambda}_{*}>0\) such that for any \(\lambda\ge\tilde{\lambda}_{*}\) our problem (\(\mathrm{S}_{0}\))-(\(\mathrm{BC}_{0}\)) (with \(\lambda=\mu\)) has at least one positive solution.

The authors thank the referees for their valuable comments and suggestions. The work of R Luca was supported by the CNCS grant PN-II-ID-PCE-2011-3-0557, Romania.

Authors and Affiliations

1. Department of Mathematics, Baylor University, Waco, TX, 76798-7328, USA

   Johnny Henderson

2. Department of Mathematics, Gh. Asachi Technical University, Iasi, 700506, Romania

   Rodica Luca

Corresponding author

Correspondence to Rodica Luca.

Competing interests

The authors declare that no competing interests exist.

Authors’ contributions

The authors contributed equally to this paper. Both authors read and approved the final manuscript.

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