Positive Solutions for a Fractional Differential Equation with Sequential Derivatives and Nonlocal Boundary Conditions

Tudorache, Alexandru; Luca, Rodica

doi:10.3390/sym14091779

Open AccessArticle

Positive Solutions for a Fractional Differential Equation with Sequential Derivatives and Nonlocal Boundary Conditions

by

Alexandru Tudorache

¹

and

Rodica Luca

^2,*

¹

Department of Computer Science and Engineering, Gh. Asachi Technical University, 700050 Iasi, Romania

²

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

^*

Author to whom correspondence should be addressed.

Symmetry 2022, 14(9), 1779; https://doi.org/10.3390/sym14091779

Submission received: 21 July 2022 / Revised: 19 August 2022 / Accepted: 23 August 2022 / Published: 26 August 2022

(This article belongs to the Special Issue Symmetry in Ordinary and Partial Differential Equations and Applications)

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Abstract

:

We study the existence of positive solutions for a Riemann–Liouville fractional differential equation with sequential derivatives, a positive parameter and a sign-changing singular nonlinearity, subject to nonlocal boundary conditions containing varied fractional derivatives and general Riemann–Stieltjes integrals. We also present the associated Green functions and some of their properties. In the proof of the main results, we apply the Guo–Krasnosel’skii fixed point theorem. Two examples are finally given that illustrate our results.

Keywords:

Riemann–Liouville fractional differential equation; nonlocal boundary conditions; sign-changing functions; singular functions; positive solutions

MSC:

34A08; 34B10; 34B16; 34B18

1. Introduction

We consider the nonlinear ordinary fractional differential equation with sequential derivatives

D_{0 +}^{β} (q (t) D_{0 +}^{γ} u (t)) = λ f (t, u (t)), t \in (0, 1),

(1)

subject to the nonlocal boundary conditions

\{\begin{matrix} u^{(j)} (0) = 0, j = 0, \dots, n - 2, D_{0 +}^{γ} u (0) = 0, \\ q (1) D_{0 +}^{γ} u (1) = \int_{0}^{1} q (t) D_{0 +}^{γ} u (t) d H_{0} (t), D_{0 +}^{α_{0}} u (1) = \sum_{i = 1}^{p} \int_{0}^{1} D_{0 +}^{α_{i}} u (t) d H_{i} (t), \end{matrix}

(2)

where

β \in (1, 2]

,

γ \in (n - 1, n]

,

n \in N

,

n \geq 3

,

p \in N

,

α_{i} \in R

,

i = 0, \dots, p

,

0 \leq α_{1} < α_{2} < \dots < α_{p} \leq α_{0} < γ - 1

,

α_{0} \geq 1

,

λ > 0

,

q : [0, 1] \to (0, \infty)

is a continuous function,

f : (0, 1) \times [0, \infty) \to R

is a continuous function which may be singular at

t = 0

and/or

t = 1

,

D_{0 +}^{κ}

denotes the Riemann–Liouville fractional derivative of order

κ

, for

κ = β, γ, α_{0}, α_{1}, \dots, α_{p}

, and the integrals from the boundary conditions (2) are Riemann–Stieltjes integrals with

H_{i}

,

i = 0, \dots, p

functions of bounded variation. The last two conditions from (2) contain symmetric cases for the fractional derivatives of

u

. For example, if

p = 1

,

H_{1} (t) = {0, t = 0; 1, t \in (0, 1]}

and

α_{1} = α_{0}

, then the last condition from (2) becomes a symmetric one, namely

D_{0 +}^{α_{0}} u (1) = D_{0 +}^{α_{0}} u (0)

. If in addition

α_{0} = 1

, we obtain the periodic condition for the first derivative of

u

, that is,

u^{'} (1) = u^{'} (0)

.

We present some assumptions for the function

f

and give intervals for the parameter

λ

such that there exists at least one positive solution of problem (1) and (2). A positive solution of (1) and (2) is a function

u \in C [0, 1]

satisfying (1) and (2) with

u (t) > 0

for all

t \in (0, 1]

. In the proofs of our main results, we apply the Guo–Krasnosel’skii fixed point theorem (see [1]). We present now some recent results connected to our problem (1) and (2). In [2], the authors investigated the existence of positive solutions for the fractional differential equation with sequential derivatives

D_{0 +}^{β} (q (t) D_{0 +}^{γ} u (t)) = λ r (t) g (t, u (t)), t \in (0, 1),

(3)

with the nonlocal boundary conditions

\{\begin{matrix} u^{(j)} (0) = 0, j = 0, \dots, n - 2, D_{0 +}^{γ} u (0) = 0, \\ q (1) D_{0 +}^{γ} u (1) = a q (ξ) D_{0 +}^{γ} u (ξ), D_{0 +}^{α_{0}} u (1) = \sum_{i = 1}^{p} \int_{0}^{1} D_{0 +}^{α_{i}} u (t) d H_{i} (t), \end{matrix}

(4)

where

β \in (1, 2]

,

γ \in (n - 1, n]

,

n \in N

,

n \geq 3

,

p \in N

,

α_{i} \in R

,

i = 0, \dots, p

,

0 \leq α_{1} < α_{2} < \dots < α_{p} \leq α_{0} < γ - 1

,

α_{0} \geq 1

,

λ > 0

,

a \geq 0

,

ξ \in (0, 1)

,

q : [0, 1] \to (0, \infty)

is a continuous function, the function

g : [0, 1] \times (0, \infty) \to [0, \infty)

is continuous and may have a singularity at the second variable in the point 0, the function

r : (0, 1) \to [0, \infty)

is continuous and may be singular at

t = 0

and/or

t = 1

, and

H_{i}

,

i = 1, \dots, p

are bounded variation functions. In the proof of the main results, they used some theorems from the fixed point index theory. In comparison with our problem (1) and (2) in which the nonlinearity

f

has arbitrary values, the nonlinearity

g

in (3) is nonnegative; in addition, the first condition from the second line of (4) is a particular case of the condition from (2), with

H_{0} (t) = {0, t \in [0, ξ); a, t \in [ξ, 1]}

. Besides this, in this paper, we use for the function

f

from (1) different assumptions than those used for the function

g

in [2]. In [3], the authors studied the existence of at least one or two positive solutions for the fractional differential equation

D_{0 +}^{α} u (t) + f (t, u (t)) = 0, t \in (0, 1),

(5)

supplemented with the boundary conditions

u (0) = u^{'} (0) = \dots = u^{(n - 2)} (0) = 0, D_{0 +}^{β_{0}} u (1) = \sum_{i = 1}^{m} \int_{0}^{1} D_{0 +}^{β_{i}} u (t) d H_{i} (t),

(6)

where

α \in R

,

n, m \in N

,

n \geq 3

,

α \in (n - 1, n]

,

β_{i} \in R

for all

i = 0, \dots, m

,

0 \leq β_{1} < β_{2} < \dots < β_{m} \leq β_{0} < α - 1

,

β_{0} \geq 1

, and the nonlinearity

f (t, u)

may change sign and may be singular at the points

t = 0

,

t = 1

and/or

u = 0

. The authors used in [3] various height functions of

f

defined on special bounded sets and the Leggett–Williams and the Krasnosel’skii fixed point index theorems. For other recent results related to the existence, nonexistence and multiplicity of positive solutions for fractional differential equations and systems with or without p-Laplacian operators, subject to varied nonlocal boundary conditions and their applications, we mention the books [4,5,6,7,8,9,10,11,12,13,14,15] and their references. Some fixed point results for a pair of fuzzy dominated mappings are presented in [11,12].

The organization of our paper is as follows. In Section 2, we investigate a linear fractional boundary value problem that is associated to problem (1) and (2) and present the associated Green functions with their properties. Section 3 is concerned with the main existence theorems for (1) and (2), and in Section 4, we give two examples that illustrate our results. Finally, Section 5 contains the conclusions for this paper.

2. Auxiliary Results

We consider the fractional differential equation

D_{0 +}^{β} (q (t) D_{0 +}^{γ} u (t)) = h (t), t \in (0, 1),

(7)

with the boundary conditions (2), where

h \in C (0, 1) \cap L^{1} (0, 1)

. We denote by

d_{1} = 1 - \int_{0}^{1} τ^{β - 1} d H_{0} (τ), d_{2} = \frac{Γ (γ)}{Γ (γ - α_{0})} - \sum_{i = 1}^{p} \frac{Γ (γ)}{Γ (γ - α_{i})} \int_{0}^{1} τ^{γ - α_{i} - 1} d H_{i} (τ) .

(8)

Lemma 1.

If

d_{1} \neq 0

and

d_{2} \neq 0

, then, the unique solution

u \in C [0, 1]

of problem (2) and (7) is

u (t) = \int_{0}^{1} G_{2} (t, s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) h (τ) d τ) d s, t \in [0, 1],

(9)

where

G_{1} (t, s) = g_{1} (t, s) + \frac{t^{β - 1}}{d_{1}} \int_{0}^{1} g_{1} (τ, s) d H_{0} (τ), (t, s) \in [0, 1] \times [0, 1],

(10)

with

g_{1} (t, s) = \frac{1}{Γ (β)} \{\begin{matrix} t^{β - 1} {(1 - s)}^{β - 1} - {(t - s)}^{β - 1}, 0 \leq s \leq t \leq 1, \\ t^{β - 1} {(1 - s)}^{β - 1}, 0 \leq t \leq s \leq 1, \end{matrix}

(11)

and

G_{2} (t, s) = g_{2} (t, s) + \frac{t^{γ - 1}}{d_{2}} \sum_{i = 1}^{p} (\int_{0}^{1} g_{3 i} (τ, s) d H_{i} (τ)), (t, s) \in [0, 1] \times [0, 1],

(12)

with

\begin{matrix} g_{2} (t, s) = \frac{1}{Γ (γ)} \{\begin{matrix} t^{γ - 1} {(1 - s)}^{γ - α_{0} - 1} - {(t - s)}^{γ - 1}, 0 \leq s \leq t \leq 1, \\ t^{γ - 1} {(1 - s)}^{γ - α_{0} - 1}, 0 \leq t \leq s \leq 1, \end{matrix} \\ g_{3 i} (t, s) = \frac{1}{Γ (γ - α_{i})} \{\begin{matrix} t^{γ - α_{i} - 1} {(1 - s)}^{γ - α_{0} - 1} - {(t - s)}^{γ - α_{i} - 1}, 0 \leq s \leq t \leq 1, \\ t^{γ - α_{i} - 1} {(1 - s)}^{γ - α_{0} - 1}, 0 \leq t \leq s \leq 1 . \end{matrix} \\ i = 1, \dots, p . \end{matrix}

(13)

Proof.

We denote by

q (t) D_{0 +}^{γ} u (t) = v (t)

. Then, problem (2) and (7) is equivalent to the following two boundary value problems:

(I): $\{\begin{matrix} D_{0 +}^{β} v (t) = h (t), t \in (0, 1), \\ v (0) = 0, v (1) = \int_{0}^{1} v (τ) d H_{0} (τ), \end{matrix}$

and
(II): $\{\begin{matrix} D_{0 +}^{γ} u (t) = v (t) / q (t), t \in (0, 1), \\ u^{(j)} (0) = 0, j = 0, \dots, n - 2, D_{0 +}^{α_{0}} u (1) = \sum_{i = 1}^{p} \int_{0}^{1} D_{0 +}^{α_{i}} u (t) d H_{i} (t) . \end{matrix}$

By Lemma 4.1.5 from [7], the unique solution

v \in C [0, 1]

of problem

(I)

is

v (t) = - \int_{0}^{1} G_{1} (t, s) h (s) d s, t \in [0, 1],

(14)

where

G_{1}

is given by (10). By Lemma 2.2 from [3], the unique solution

u \in C [0, 1]

of problem

(II)

is

u (t) = - \int_{0}^{1} G_{2} (t, s) v (s) / q (s) d s, t \in [0, 1],

(15)

where

G_{2}

is given by (12). By using now (14) and (15) we obtain the solution

u

of problem (2) and (7) given by relation (9). □

We present now some properties of functions

g_{1}, g_{2}, g_{3 i}, i = 1, \dots, p

from [7,16].

Lemma 2.

The functions

g_{1}, g_{2}, g_{3 i}, i = 1, \dots, p

given by (11) and (13) have the properties

(a): $g_{1}, g_{2}, g_{3 i} : [0, 1] \times [0, 1] \to [0, \infty)$ , $i = 1, \dots, p$ are continuous functions, and $g_{1} (t, s) > 0$ , $g_{2} (t, s) > 0$ and $g_{3 i} (t, s) > 0$ for all $(t, s) \in (0, 1) \times (0, 1)$ ;
(b): $g_{1} (t, s) \leq h_{1} (s), \forall (t, s) \in [0, 1] \times [0, 1]$ , where $h_{1} (s) = \frac{1}{Γ (β)} {(1 - s)}^{β - 1}$ , $s \in [0, 1]$ ;
(c): $g_{2} (t, s) \leq h_{2} (s), \forall (t, s) \in [0, 1] \times [0, 1]$ , where $h_{2} (s) = \frac{1}{Γ (γ)} {(1 - s)}^{γ - α_{0} - 1} (1 - {(1 - s)}^{α_{0}}), s \in [0, 1]$ ;
(d): $g_{2} (t, s) \geq t^{γ - 1} h_{2} (s), \forall (t, s) \in [0, 1] \times [0, 1]$ ;
(e): $g_{3 i} (t, s) \leq \frac{1}{Γ (γ - α_{i})} t^{γ - α_{i} - 1}$ , $g_{3 i} (t, s) \leq \frac{1}{Γ (γ - α_{i})} {(1 - s)}^{γ - α_{0} - 1}, \forall (t, s) \in [0, 1] \times [0, 1], i = 1, \dots, p$ ;
(f): $g_{3 i} (t, s) \geq t^{γ - α_{i} - 1} h_{3 i} (s), \forall (t, s) \in [0, 1] \times [0, 1]$ , where $h_{3 i} (s) = \frac{1}{Γ (γ - α_{i})} {(1 - s)}^{γ - α_{0} - 1}$ $(1 - {(1 - s)}^{α_{0} - α_{i}}), s \in [0, 1], i = 1, \dots, p$ .

By using the properties of the functions

g_{1}, g_{2}, g_{3 i}, i = 1, \dots, p

presented in Lemma 2, we obtain the following result.

Lemma 3.

If

d_{1} > 0

,

d_{2} > 0

,

H_{i}, i = 0, \dots, p

are nondecreasing functions, then the functions

G_{1}

and

G_{2}

given by (10) and (12) have the properties:

(a): $G_{1}, G_{2} : [0, 1] \times [0, 1] \to [0, \infty)$ are continuous functions;
(b): $G_{1} (t, s) \leq J_{1} (s), \forall (t, s) \in [0, 1] \times [0, 1]$ , where

$J_{1} (s) = h_{1} (s) + \frac{1}{d_{1}} \int_{0}^{1} g_{1} (τ, s) d H_{0} (τ), \forall s \in [0, 1];$
(c): $G_{2} (t, s) \leq J_{2} (s), \forall (t, s) \in [0, 1] \times [0, 1]$ , where

$J_{2} (s) = h_{2} (s) + \frac{1}{d_{2}} \sum_{i = 1}^{p} \int_{0}^{1} g_{3 i} (τ, s) d H_{i} (τ), \forall s \in [0, 1];$
(d): $G_{2} (t, s) \geq t^{γ - 1} J_{2} (s), \forall (t, s) \in [0, 1] \times [0, 1]$ ;
(e): $G_{2} (t, s) \leq σ t^{γ - 1}, \forall (t, s) \in [0, 1] \times [0, 1]$ , where

$σ = \frac{1}{Γ (γ)} + \frac{1}{d_{2}} \sum_{i = 1}^{p} \frac{1}{Γ (γ - α_{i})} \int_{0}^{1} τ^{γ - α_{i} - 1} d H_{i} (τ) .$

Lemma 4.

If

d_{1} > 0

,

d_{2} > 0

,

H_{i}, i = 0, \dots, p

are nondecreasing functions, and

h \in C (0, 1) \cap L^{1} (0, 1)

with

h (t) \geq 0

for all

t \in (0, 1)

, then, the solution

u

of problem (2) and (7) given by (9) satisfies the properties

u (t) \geq 0

for all

t \in [0, 1]

and

u (t) \geq t^{γ - 1} u (ζ)

for all

t, ζ \in [0, 1]

.

Proof.

By using the properties from Lemma 3, we have

u (t) \geq 0

for all

t \in [0, 1]

. In addition, we obtain

\begin{matrix} u (t) \geq \int_{0}^{1} t^{γ - 1} J_{2} (s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) h (τ) d τ) d s \\ \geq t^{γ - 1} \int_{0}^{1} G_{2} (ζ, s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) h (τ) d τ) d s = t^{γ - 1} u (ζ), \forall t, ζ \in [0, 1] . \end{matrix}

□

3. Existence of Positive Solutions

In this section, we study the existence of positive solutions for our problem (1) and (2). We present the assumptions that we use in this section.

(I1): $β \in (1, 2]$ , $n \in N$ , $n \geq 3$ , $γ \in (n - 1, n]$ , $p \in N$ , $α_{i} \in R$ , $i = 0, \dots, p$ , $0 \leq α_{1} < \dots < α_{p} \leq α_{0} < γ - 1$ , $α_{0} \geq 1$ , $d_{1} > 0$ , $d_{2} > 0$ , $H_{i} : [0, 1] \to R, i = 0, \dots, p$ are nondecreasing functions, $λ > 0$ , $q \in C ([0, 1], (0, \infty))$ , ( $d_{1}, d_{2}$ are given by (8)).
(I2): The function $f \in C ((0, 1) \times [0, \infty), R)$ may have a singularity at $t = 0$ and/or $t = 1$ , and there exist the functions $ξ, φ \in C ((0, 1), [0, \infty))$ , $ψ \in C ([0, 1] \times [0, \infty), [0, \infty))$ such that

$- ξ (t) \leq f (t, x) \leq φ (t) ψ (t, x), \forall t \in (0, 1), x \in [0, \infty),$

with $0 < \int_{0}^{1} ξ (s) d s < \infty$ , $0 < \int_{0}^{1} φ (s) d s < \infty$ .
(I3): There exist $θ_{1}, θ_{2} \in (0, 1)$ , $θ_{1} < θ_{2}$ such that $f_{\infty} = lim_{x \to \infty} min_{t \in [θ_{1}, θ_{2}]} \frac{f (t, x)}{x} = \infty$ .
(I4): There exist $θ_{1}, θ_{2} \in (0, 1)$ , $θ_{1} < θ_{2}$ such that $\underset{x \to \infty}{lim inf} min_{t \in [θ_{1}, θ_{2}]} f (t, x) > Ξ_{0}$ , and $ψ_{\infty} = lim_{x \to \infty} max_{t \in [0, 1]} \frac{ψ (t, x)}{x} = 0$ , where

$Ξ_{0} = \frac{2 σ ω}{θ_{1}^{γ - 1}} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) {(\int_{θ_{1}}^{θ_{2}} J_{2} (s) (\frac{1}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) d τ) d s)}^{- 1},$

$ω = {max}_{s \in [0, 1]} J_{1} (s)$ , and $σ, G_{1} J_{1}, J_{2}$ are given in Lemmas 1 and 3.

We consider the fractional differential equation

D_{0 +}^{β} (q (t) D_{0 +}^{γ} v (t)) = λ (f (t, {[v (t) - λ ζ (t)]}^{*}) + ξ (t)) = 0, t \in (0, 1),

(16)

with the nonlocal boundary conditions

\{\begin{matrix} v^{(j)} (0) = 0, j = 0, \dots, n - 2, D_{0 +}^{γ} v (0) = 0, \\ q (1) D_{0 +}^{γ} v (1) = \int_{0}^{1} q (t) D_{0 +}^{γ} v (t) d H_{0} (t), D_{0 +}^{α_{0}} v (1) = \sum_{i = 1}^{p} \int_{0}^{1} D_{0 +}^{α_{i}} v (t) d H_{i} (t), \end{matrix}

(17)

where

w {(t)}^{*} = w (t)

if

w (t) \geq 0

, and

w {(t)}^{*} = 0

if

w (t) < 0

. Here

ζ (t) = \int_{0}^{1} G_{2} (t, s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) ξ (τ) d τ) d s, t \in [0, 1]

is the solution of problem

\{\begin{matrix} D_{0 +}^{β} (q (t) D_{0 +}^{γ} ζ (t)) = ξ (t), t \in (0, 1), \\ ζ^{(j)} (0) = 0, j = 0, \dots, n - 2, D_{0 +}^{γ} ζ (0) = 0, \\ q (1) D_{0 +}^{γ} ζ (1) = \int_{0}^{1} q (t) D_{0 +}^{γ} ζ (t) d H_{0} (t), D_{0 +}^{α_{0}} ζ (1) = \sum_{i = 1}^{p} \int_{0}^{1} D_{0 +}^{α_{i}} ζ (t) d H_{i} (t) . \end{matrix}

(18)

Under assumptions

(I 1), (I 2)

, we obtain

ζ (t) \geq 0

for all

t \in [0, 1]

. We show that there exists a solution

v

of problem (16) and (17) with

v (t) \geq λ ζ (t)

on

[0, 1]

and

v (t) > λ ζ (t)

on

(0, 1]

. In this case,

u = v - λ ζ

represents a positive solution of problem (1) and (2). Hence, in what follows, we study problem (16) and (17). By using Lemma 1,

v

is a solution of problem (16) and (17) if and only if

v

is a solution of equation

v (t) = λ \int_{0}^{1} G_{2} (t, s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s, t \in [0, 1] .

We introduce the Banach space

X = C [0, 1]

with the supremum norm

∥ \cdot ∥

, and the cone

Q = {v \in X, v (t) \geq t^{γ - 1} ∥ v ∥, \forall t \in [0, 1]} .

For

λ > 0

we also define the operator

A : X \to X

given by

A v (t) = λ \int_{0}^{1} G_{2} (t, s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s,

for

t \in [0, 1]

and

v \in X .

Lemma 5.

We suppose that assumptions

(I 1)

and

(I 2)

hold. Then,

A : Q \to Q

is a completely continuous operator.

Proof.

Let

v \in Q

be fixed. By using

(I 1)

and

(I 2)

, we find that

A v (t) < \infty

for all

t \in [0, 1]

. In addition, by Lemma 3, we obtain for all

t, t^{'} \in [0, 1]

A v (t) \leq λ \int_{0}^{1} J_{2} (s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s,

and

\begin{matrix} A v (t) \geq λ \int_{0}^{1} t^{γ - 1} J_{2} (s) (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s \\ \geq t^{γ - 1} A v (t^{'}) . \end{matrix}

Hence,

A v (t) \geq t^{γ - 1} ∥ A v ∥

for all

t \in [0, 1]

. We conclude that

A v \in Q

, and hence

A (Q) \subset Q

. With a standard approach, we deduce that

A : Q \to Q

is a completely continuous operator. □

Theorem 1.

We suppose that assumptions

(I 1)

,

(I 2)

and

(I 3)

hold. Then, there exists

λ_{1} > 0

such that for any

λ \in (0, λ_{1}]

, the problem (1) and (2) has at least one positive solution.

Proof.

We consider a positive number

r_{1} > σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)

, and we define the set

Y_{1} = {v \in X, ∥ v ∥ < r_{1}}

. We also define

λ_{1} = min \{1, r_{1} {(\int_{0}^{1} \frac{1}{q (s)} J_{2} (s) d s)}^{- 1} {(Λ_{1} \int_{0}^{1} J_{1} (τ) (φ (τ) + ξ (τ)) d τ)}^{- 1}\},

with

Λ_{1} = max {{max}_{t \in [0, 1], x \in [0, r_{1}]} ψ (t, x), 1}

.

Let

λ \in (0, λ_{1}]

. Because

\begin{matrix} ζ (t) \leq \int_{0}^{1} σ t^{γ - 1} (\frac{1}{q (s)} \int_{0}^{1} G_{1} (s, τ) ξ (τ) d τ) d s \\ \leq σ t^{γ - 1} \int_{0}^{1} \frac{1}{q (s)} (\int_{0}^{1} J_{1} (τ) ξ (τ) d τ) d s \\ \leq σ ω t^{γ - 1} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ), \forall t \in [0, 1], \end{matrix}

we find for any

v \in Q \cap \partial Y_{1}

and

t \in [0, 1]

{[v (t) - λ ζ (t)]}^{*} \leq v (t) \leq ∥ v ∥ \leq r_{1},

and

\begin{matrix} v (t) - λ ζ (t) \geq t^{γ - 1} ∥ v ∥ - λ σ ω t^{γ - 1} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \\ = t^{γ - 1} [r_{1} - λ σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \\ \geq t^{γ - 1} [r_{1} - λ_{1} σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \\ \geq t^{γ - 1} [r_{1} - σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \geq 0 . \end{matrix}

(19)

Therefore, for any

v \in Q \cap \partial Y_{1}

and

t \in [0, 1]

, we deduce

\begin{matrix} A v (t) \leq λ \int_{0}^{1} J_{2} (s) (\frac{1}{q (s)} \int_{0}^{1} J_{1} (τ) (φ (τ) ψ {(τ, [v τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s \\ \leq λ_{1} (\int_{0}^{1} \frac{1}{q (s)} J_{2} (s) d s) (Λ_{1} \int_{0}^{1} J_{1} (τ) (φ (τ) + ξ (τ)) d τ) \leq r_{1} = ∥ v ∥ . \end{matrix}

Hence, we conclude

∥ A v ∥ \leq ∥ v ∥, \forall v \in Q \cap \partial Y_{1} .

(20)

Next, for

θ_{1}, θ_{2} \in (0, 1)

,

θ_{1} < θ_{2}

given in

(I 3)

, we choose a constant

Ξ_{1} > 0

such that

Ξ_{1} \geq \frac{2}{λ θ_{1}^{β + γ - 2}} {(\int_{θ_{1}}^{θ_{2}} \frac{1}{q (s)} J_{2} (s) (\int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) d τ) d s)}^{- 1} .

By

(I 3)

, we deduce that there exists a constant

Λ_{0} > 0

such that

f (t, x) \geq Ξ_{1} x, \forall t \in [θ_{1}, θ_{2}], x \geq Λ_{0} .

(21)

We define now

r_{2} = max \{2 r_{1}, 2 Λ_{0} / θ_{1}^{γ - 1}\}

and let

Y_{2} = {v \in X, ∥ v ∥ < r_{2}}

. Then, for any

v \in Q \cap \partial Y_{2}

, we obtain as in (19)

\begin{matrix} v (t) - λ ζ (t) \geq t^{γ - 1} [r_{2} - σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \\ \geq t^{γ - 1} [r_{1} - σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \geq 0, \forall t \in [0, 1] . \end{matrix}

Hence, we find

\begin{matrix} {[v (t) - λ ζ (t)]}^{*} = v (t) - λ ζ (t) \geq t^{γ - 1} [r_{2} - σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \\ \geq \frac{θ_{1}^{γ - 1} r_{2}}{2} \geq Λ_{0}, \forall t \in [θ_{1}, θ_{2}] . \end{matrix}

(22)

Then, for any

v \in Q \cap \partial Y_{2}

and

t \in [θ_{1}, θ_{2}]

, by (21) and (22), we deduce

\begin{matrix} A v (t) \geq λ \int_{θ_{1}}^{θ_{2}} G_{2} (t, s) (\frac{1}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s \\ \geq λ \int_{θ_{1}}^{θ_{2}} G_{2} (t, s) (\frac{1}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) (Ξ_{1} {[v (τ) - λ ζ (τ)]}^{*} + ξ (τ)) d τ) d s \\ \geq λ \int_{θ_{1}}^{θ_{2}} G_{2} (t, s) (\frac{Ξ_{1}}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) {[v (τ) - λ ζ (τ)]}^{*} d τ) d s \\ \geq \frac{λ θ_{1}^{β + γ - 2} Ξ_{1} r_{2}}{2} (\int_{θ_{1}}^{θ_{2}} \frac{1}{q (s)} J_{2} (s) (\int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) d τ) d s) \geq r_{2} = ∥ v ∥ . \end{matrix}

So,

∥ A v ∥ \geq ∥ v ∥, \forall v \in Q \cap \partial Y_{2} .

(23)

By (20) and (23) and the Guo–Krasnosel’skii fixed point theorem, we conclude that

A

has a fixed point

v_{1} \in Q \cap ({\bar{Y}}_{2} \ Y_{1})

, that is,

r_{1} \leq ∥ v_{1} ∥ \leq r_{2}

. Since

∥ v_{1} ∥ \geq r_{1}

, we obtain

\begin{matrix} v_{1} (t) - λ ζ (t) \geq t^{γ - 1} ∥ v_{1} ∥ - λ σ ω t^{γ - 1} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \\ \geq t^{γ - 1} [r_{1} - σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] = Ξ_{2} t^{γ - 1}, \forall t \in [0, 1], \end{matrix}

where

Ξ_{2} = r_{1} - σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)

, and so

v_{1} (t) \geq λ ζ (t) + Ξ_{2} t^{γ - 1}

for all

t \in [0, 1]

. Let

u_{1} (t) = v_{1} (t) - λ ζ (t)

for all

t \in [0, 1]

. Then

u_{1}

is a positive solution of problem (1) and (2) with

u_{1} (t) \geq Ξ_{2} t^{γ - 1}

for all

t \in [0, 1]

. □

Theorem 2.

We suppose that assumptions

(I 1)

,

(I 2)

and

(I 4)

hold. Then, there exists

λ_{2} > 0

such that for any

λ \in [λ_{2}, \infty)

, the problem (1) and (2) has at least one positive solution.

Proof.

By

(I 4)

there exists

Λ_{2} > 0

such that

f (t, x) \geq Ξ_{0}

, for all

t \in [θ_{1}, θ_{2}]

and

x \geq Λ_{2} .

We define

λ_{2} = \frac{Λ_{2}}{θ_{1}^{γ - 1} σ ω} {(\int_{0}^{1} \frac{1}{q (s)} d s)}^{- 1} {(\int_{0}^{1} ξ (τ) d τ)}^{- 1}

. We suppose now

λ \geq λ_{2}

. Let

r_{3} = 2 λ σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)

, and

Y_{3} = {v \in X, ∥ v ∥ < r_{3}}

. Then for any

v \in Q \cap \partial Y_{3}

, we obtain

\begin{matrix} v (t) - λ ζ (t) \geq t^{γ - 1} ∥ v ∥ - λ σ ω t^{γ - 1} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \\ = t^{γ - 1} [r_{3} - λ σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \\ = t^{γ - 1} λ σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \\ \geq t^{γ - 1} λ_{2} σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) = \frac{Λ_{2} t^{γ - 1}}{θ_{1}^{γ - 1}} \geq 0, \forall t \in [0, 1] . \end{matrix}

(24)

Then, for any

v \in Q \cap \partial Y_{3}

and

t \in [θ_{1}, θ_{2}]

, we find

{[v (t) - λ ζ (t)]}^{*} = v (t) - λ ζ (t) \geq \frac{Λ_{2} t^{γ - 1}}{θ_{1}^{γ - 1}} \geq Λ_{2} .

Hence, for any

v \in Q \cap \partial Y_{3}

and

t \in [θ_{1}, θ_{2}]

, we deduce

\begin{matrix} A v (t) \geq λ \int_{θ_{1}}^{θ_{2}} G_{2} (t, s) (\frac{1}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s \\ \geq λ \int_{θ_{1}}^{θ_{2}} t^{γ - 1} J_{2} (s) (\frac{1}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s \\ \geq λ \int_{θ_{1}}^{θ_{2}} t^{γ - 1} J_{2} (s) (\frac{1}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) (Ξ_{0} + ξ (τ)) d τ) d s \\ \geq λ Ξ_{0} t^{γ - 1} \int_{θ_{1}}^{θ_{2}} J_{2} (s) (\frac{1}{q (s)} \int_{θ_{1}}^{θ_{2}} G_{1} (s, τ) d τ) d s = \frac{r_{3} t^{γ - 1}}{θ_{1}^{γ - 1}} \geq r_{3} . \end{matrix}

Therefore, we conclude

∥ A v ∥ \geq ∥ v ∥, \forall v \in Q \cap \partial Y_{3} .

(25)

Next, we consider the positive number

ϵ = {(2 λ \int_{0}^{1} J_{2} (s) \frac{1}{q (s)} d s)}^{- 1} {(\int_{0}^{1} J_{1} (τ) φ (τ) d τ)}^{- 1}

. Then by

(I 4)

we obtain that there exists

Λ_{3} > 0

such that

ψ (t, x) \leq ϵ x

for all

t \in [0, 1]

and

x \geq Λ_{3}

. Then, we find

ψ (t, x) \leq Λ_{4} + ϵ x

for all

t \in [0, 1]

,

x \geq 0

, where

Λ_{4} = {max}_{t \in [0, 1], x \in [0, Λ_{3}]} ψ (t, x)

. We define

r_{4} > max \{r_{3}, 2 λ max {Λ_{4}, 1} (\int_{0}^{1} J_{2} (s) \frac{1}{q (s)} d s) (\int_{0}^{1} J_{1} (τ) (φ (τ) + ξ (τ)) d τ)\},

and

Y_{4} = {v \in Q, ∥ v ∥ < r_{4}}

.

Hence, for any

v \in Q \cap \partial Y_{4}

, we deduce as in (24)

\begin{matrix} v (t) - λ ζ (t) \geq t^{γ - 1} [r_{4} - λ σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \\ \geq t^{γ - 1} [r_{3} - λ σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ)] \geq \frac{Λ_{2} t^{γ - 1}}{θ_{1}^{γ - 1}} \geq 0, \forall t \in [0, 1] . \end{matrix}

(26)

So, for any

v \in Q \cap \partial Y_{4}

, we obtain

\begin{matrix} A v (t) \leq λ \int_{0}^{1} J_{2} (s) (\frac{1}{q (s)} \int_{0}^{1} J_{1} (τ) (f (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s \\ \leq λ \int_{0}^{1} J_{2} (s) (\frac{1}{q (s)} \int_{0}^{1} J_{1} (τ) (φ (τ) ψ (τ, {[v (τ) - λ ζ (τ)]}^{*}) + ξ (τ)) d τ) d s \\ \leq λ \int_{0}^{1} J_{2} (s) \{\frac{1}{q (s)} \int_{0}^{1} J_{1} (τ) [φ (τ) (Λ_{4} + ϵ ({[v (τ) - λ ζ (τ)]}^{*})) + ξ (τ)] d τ\} d s \\ \leq λ max {Λ_{4}, 1} \int_{0}^{1} J_{2} (s) [\frac{1}{q (s)} \int_{0}^{1} J_{1} (τ) (φ (τ) + ξ (τ)) d τ] d s \\ + λ ϵ r_{4} \int_{0}^{1} J_{2} (s) (\frac{1}{q (s)} \int_{0}^{1} J_{1} (s) φ (τ) d τ) d s \\ \leq λ max {Λ_{4}, 1} (\int_{0}^{1} J_{2} (s) \frac{1}{q (s)} d s) (\int_{0}^{1} J_{1} (τ) (φ (τ) + ξ (τ)) d τ) \\ + λ ϵ r_{4} (\int_{0}^{1} J_{2} (s) \frac{1}{q (s)} d s) (\int_{0}^{1} J_{1} (τ) φ (τ) d τ) \\ \leq \frac{r_{4}}{2} + \frac{r_{4}}{2} = r_{4} = ∥ v ∥, \forall t \in [0, 1] . \end{matrix}

Hence,

∥ A v ∥ \leq ∥ v ∥, \forall v \in Q \cap \partial Y_{4} .

(27)

By (25) and (27) and the Guo–Krasnosel’skii fixed point theorem, we conclude that

A

has a fixed point

v_{2} \in Q \cap ({\bar{Y}}_{4} \ Y_{3})

, so

r_{3} \leq ∥ v_{2} ∥ \leq r_{4} .

Besides this, similar to (26), we find for all

t \in [0, 1]

\begin{matrix} v_{2} (t) - λ ζ (t) \geq v_{2} (t) - λ σ ω t^{γ - 1} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \\ \geq t^{γ - 1} ∥ v_{2} ∥ - λ σ ω t^{γ - 1} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \\ \geq t^{γ - 1} r_{3} - λ σ ω t^{γ - 1} (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \geq \frac{Λ_{2} t^{γ - 1}}{θ_{1}^{γ - 1}} . \end{matrix}

Let

u_{2} (t) = v_{2} (t) - λ ζ (t)

for all

t \in [0, 1]

. Then,

u_{2} (t) \geq Ξ_{3} t^{γ - 1}

for all

t \in [0, 1]

, where

Ξ_{3} = Λ_{2} / θ_{1}^{γ - 1}

. Therefore, we deduce that

u_{2}

is a positive solution of problem (1) and (2). □

With a similar proof to that of Theorem 2, we obtain the next result.

Theorem 3.

We suppose that assumptions

(I 1)

,

(I 2)

and

$\tilde{(I 4)}$: There exist $θ_{1}, θ_{2} \in (0, 1)$ , $θ_{1} < θ_{2}$ such that ${\tilde{f}}_{\infty} = lim_{x \to \infty} min_{t \in [θ_{1}, θ_{2}]} f (t, x) = \infty$ , and $ψ_{\infty} = lim_{x \to \infty} max_{t \in [0, 1]} \frac{ψ (t, x)}{x} = 0$ ,

hold. Then, there exists

{\tilde{λ}}_{2} > 0

such that for any

λ \in [{\tilde{λ}}_{2}, \infty)

, the boundary value problem (1) and (2) has at least one positive solution.

4. Examples

Let

β = 3 / 2

,

γ = 8 / 3

(

n = 3

),

p = 2

,

α_{0} = 7 / 6

,

α_{1} = 6 / 5

,

α_{2} = 5 / 4

,

q (t) = \frac{1}{t + 2}

for all

t \in [0, 1]

,

H_{0} (t) = {1, t \in [0, 1 / 5); 7 / 3, t \in [1 / 5, 1]}

,

H_{1} (t) = t / 4

for all

t \in [0, 1]

, and

H_{2} (t) = {2, t \in [0, 1 / 3); 28 / 9, t \in [1 / 3, 1]} .

We consider the fractional differential equation

D_{0 +}^{3 / 2} (\frac{1}{t + 2} D_{0 +}^{8 / 3} u (t)) = λ f (t, u (t)), t \in (0, 1),

(28)

with the boundary conditions

\{\begin{matrix} u (0) = u^{'} (0) = 0, D_{0 +}^{8 / 3} u (0) = 0, D_{0 +}^{8 / 3} u (1) = \frac{20}{11} D_{0^{+}}^{8 / 3} u (\frac{1}{5}), \\ D_{0 +}^{7 / 6} u (1) = \frac{1}{4} \int_{0}^{1} D_{0 +}^{6 / 5} u (t) d t + \frac{10}{9} D_{0 +}^{5 / 4} u (\frac{1}{3}) . \end{matrix}

(29)

We obtain for this problem

d_{1} \approx 0.40371521 > 0

and

d_{2} \approx 0.214979 > 0

, so assumption

(I 1)

is satisfied. In addition, we find

\begin{array}{l} \begin{matrix} g_{1} (t, s) = \frac{1}{Γ (3 / 2)} \{\begin{matrix} t^{1 / 2} {(1 - s)}^{1 / 2} - {(t - s)}^{1 / 2}, 0 \leq s \leq t \leq 1, \\ t^{1 / 2} {(1 - s)}^{1 / 2}, 0 \leq t \leq s \leq 1, \end{matrix} \end{matrix} \\ \begin{matrix} g_{2} (t, s) = \frac{1}{Γ (8 / 3)} \{\begin{matrix} t^{5 / 3} {(1 - s)}^{1 / 2} - {(t - s)}^{5 / 3}, 0 \leq s \leq t \leq 1, \\ t^{5 / 3} {(1 - s)}^{1 / 2}, 0 \leq t \leq s \leq 1, \end{matrix} \end{matrix} \\ \begin{matrix} g_{31} (t, s) = \frac{1}{Γ (22 / 15)} \{\begin{matrix} t^{7 / 15} {(1 - s)}^{1 / 2} - {(t - s)}^{7 / 15}, 0 \leq s \leq t \leq 1, \\ t^{7 / 15} {(1 - s)}^{1 / 2}, 0 \leq t \leq s \leq 1, \end{matrix} \end{matrix} \\ \begin{matrix} g_{32} (t, s) = \frac{1}{Γ (17 / 22)} \{\begin{matrix} t^{5 / 12} {(1 - s)}^{1 / 2} - {(t - s)}^{5 / 12}, 0 \leq s \leq t \leq 1, \\ t^{5 / 12} {(1 - s)}^{1 / 2}, 0 \leq t \leq s \leq 1, \end{matrix} \end{matrix} \\ G_{1} (t, s) = g_{1} (t, s) + \frac{4 t^{1 / 2}}{3 d_{1}} g_{1} (\frac{1}{5}, s) \\ = \{\begin{matrix} \frac{1}{Γ (3 / 2)} t^{1 / 2} {(1 - s)}^{1 / 2} + \frac{4 t^{1 / 2}}{3 d_{1} Γ (3 / 2)} [{(\frac{1}{5})}^{1 / 2} {(1 - s)}^{1 / 2} - {(\frac{1}{5} - s)}^{1 / 2}], t \leq s < \frac{1}{5}, \\ \frac{1}{Γ (3 / 2)} [t^{1 / 2} {(1 - s)}^{1 / 2} - {(t - s)}^{1 / 2}] + \frac{4 t^{1 / 2}}{3 d_{1} Γ (3 / 2)} [{(\frac{1}{5})}^{1 / 2} {(1 - s)}^{1 / 2} - {(\frac{1}{5} - s)}^{1 / 2}], \\ s < \frac{1}{5}, s \leq t, \\ \frac{1}{Γ (3 / 2)} t^{1 / 2} {(1 - s)}^{1 / 2} + \frac{4 t^{1 / 2}}{3 d_{1} Γ (3 / 2)} {(\frac{1}{5})}^{1 / 2} {(1 - s)}^{1 / 2}, t \leq s, \frac{1}{5} \leq s, \\ \frac{1}{Γ (3 / 2)} [t^{1 / 2} {(1 - s)}^{1 / 2} - {(t - s)}^{1 / 2}] + \frac{4 t^{1 / 2}}{3 d_{1} Γ (3 / 2)} {(\frac{1}{5})}^{1 / 2} {(1 - s)}^{1 / 2}, \frac{1}{5} \leq s \leq t, \end{matrix} \\ G_{2} (t, s) = g_{2} (t, s) + \frac{t^{5 / 3}}{d_{2}} [\frac{1}{4} \int_{0}^{1} g_{31} (τ, s) d τ + \frac{10}{9} g_{32} (\frac{1}{3}, s)], t, s \in [0, 1], \\ h_{1} (s) = \frac{1}{Γ (3 / 2)} {(1 - s)}^{1 / 2}, h_{2} (s) = \frac{1}{Γ (8 / 3)} ({(1 - s)}^{1 / 2} {(1 - s)}^{5 / 3}), s \in [0, 1], \\ J_{1} (s) = \{\begin{matrix} h_{1} (s) + \frac{4}{3 d_{1} Γ (3 / 2)} [{(\frac{1}{5})}^{1 / 2} {(1 - s)}^{1 / 2} - {(\frac{1}{5} - s)}^{1 / 2}], 0 \leq s < \frac{1}{5}, \\ h_{1} (s) + \frac{4}{3 d_{1} Γ (3 / 2)} {(\frac{1}{5})}^{1 / 2} {(1 - s)}^{1 / 2}, \frac{1}{5} \leq s \leq 1, \end{matrix} \\ J_{2} (s) = \{\begin{matrix} h_{2} (s) + \frac{1}{d_{2}} \{\frac{1}{4 Γ (37 / 15)} {(1 - s)}^{1 / 2} - \frac{1}{4 Γ (37 / 15)} {(1 - s)}^{22 / 15} \\ + \frac{10}{9 Γ (17 / 12)} [{(\frac{1}{3})}^{5 / 12} {(1 - s)}^{1 / 2} - {(\frac{1}{3} - s)}^{5 / 12}]\}, 0 \leq s < \frac{1}{3}, \\ h_{2} (s) + \frac{1}{d_{2}} [\frac{1}{4 Γ (37 / 15)} {(1 - s)}^{1 / 2} - \frac{1}{4 Γ (37 / 15)} {(1 - s)}^{22 / 15} \\ + \frac{10}{9 Γ (17 / 12)} {(\frac{1}{3})}^{5 / 12} {(1 - s)}^{1 / 2}], \frac{1}{3} \leq s \leq 1, \end{matrix} \\ ω = max_{s \in [0, 1]} J_{2} (s) \approx 2.49991328, σ \approx 5.24878784 . \end{array}

Example 1.

We consider the function

f (t, x) = \frac{x^{2} - x + 1}{3 \sqrt[5]{t^{2} {(1 - t)}^{3}}} + ln t, t \in (0, 1), x \geq 0 .

(30)

We have

ξ (t) = - ln t

and

φ (t) = \frac{1}{\sqrt[5]{t^{2} {(1 - t)}^{3}}}

for all

t \in (0, 1)

,

ψ (t, x) = \frac{x^{2} - x + 1}{3}

for all

t \in [0, 1]

and

x \geq 0

, and

\int_{0}^{1} ξ (t) d t = 1

,

\int_{0}^{1} φ (t) d t = B (\frac{3}{5}, \frac{2}{5}) \approx 3.303266

. Then, assumption

(I 2)

is satisfied. Besides this, for

θ_{1}, θ_{2}

fixed,

0 < θ_{1} < θ_{2} < 1

, we find

f_{\infty} = \infty

, so assumption

(I 3)

is also satisfied. We also obtain

σ ω (\int_{0}^{1} \frac{1}{q (s)} d s) (\int_{0}^{1} ξ (τ) d τ) \approx 32.80378616

, and then we choose

r_{1} = 33

. We also have

Λ_{1} = \frac{1057}{3}

,

a : = \int_{0}^{1} \frac{1}{q (s)} J_{2} (s) d s \approx 5.14534034

,

b : = \int_{0}^{1} J_{1} (τ) (φ (τ) + ξ (τ)) d τ \approx 5.93232294

, and then

λ_{1} = min {1, r_{1} {(a b Λ_{1})}^{- 1}} \approx 0.00306847

. By Theorem 1, we deduce that problem (28) and (29) with the nonlinearity (30) has at least one positive solution for any

λ \in (0, λ_{1}]

.

Example 2.

We consider the function

f (t, x) = \frac{\sqrt{x + 1}}{2 \sqrt[3]{t^{2} (1 - t)}} - \frac{1}{\sqrt[4]{t}}, t \in (0, 1), x \geq 0 .

(31)

Here we have

ξ (t) = \frac{1}{\sqrt[4]{t}}

and

φ (t) = \frac{1}{\sqrt[3]{t^{2} (1 - t)}}

for all

t \in (0, 1)

,

ψ (t, x) = \frac{\sqrt{x + 1}}{2}

for all

t \in [0, 1]

and

x \geq 0

. For

θ_{1}, θ_{2}

fixed,

0 < θ_{1} < θ_{2} < 1

, the assumptions

(I 2)

and

(I 4)

are satisfied, (

\int_{0}^{1} ξ (t) d t = 4 / 3

,

\int_{0}^{1} φ (t) d t = B (\frac{1}{3}, \frac{2}{3}) \approx 3.62759873

,

{lim}_{x \to \infty} {min}_{t \in [θ_{1}, θ_{2}]} f (t, x) = \infty

and

ψ_{\infty} = 0

).

For

θ_{1} = 1 / 4

,

θ_{2} = 3 / 4

, we obtain

\begin{matrix} A = \int_{1 / 4}^{3 / 4} J_{2} (s) (\frac{1}{q (s)} \int_{1 / 4}^{3 / 4} G_{1} (s, τ) d τ) d s \\ = \int_{1 / 4}^{3 / 4} J_{2} (s) (s + 2) \{\int_{1 / 4}^{s} \{\frac{1}{Γ (3 / 2)} [s^{1 / 2} {(1 - τ)}^{1 / 2} - {(s - τ)}^{1 / 2}] \\ + \frac{4 s^{1 / 2}}{3 d_{1} Γ (3 / 2)} {(\frac{1}{5})}^{1 / 2} {(1 - τ)}^{1 / 2}\} d τ \\ + \int_{s}^{3 / 4} \{\frac{1}{Γ (3 / 2)} s^{1 / 2} {(1 - τ)}^{1 / 2} + \frac{4 s^{1 / 2}}{3 d_{1} Γ (3 / 2)} {(\frac{1}{5})}^{1 / 2} {(1 - τ)}^{1 / 2}\} d τ\} d s \\ = \int_{1 / 4}^{3 / 4} J_{2} (s) (s + 2) [\frac{1}{Γ (5 / 2)} s^{1 / 2} {(\frac{3}{4})}^{3 / 2} - \frac{1}{Γ (5 / 2)} {(s - \frac{1}{4})}^{3 / 2} \\ + \frac{4 s^{1 / 2}}{3 d_{1} Γ (5 / 2)} {(\frac{1}{5})}^{1 / 2} {(\frac{3}{4})}^{3 / 2} - \frac{1}{Γ (5 / 2)} s^{1 / 2} {(\frac{1}{4})}^{3 / 2} \\ - \frac{4 s^{1 / 2}}{3 d_{1} Γ (5 / 2)} {(\frac{1}{5})}^{1 / 2} {(\frac{1}{4})}^{3 / 2}] d s \approx 2.09114717 . \end{matrix}

In addition, we find

Ξ_{0} = \frac{20}{3} 4^{5 / 3} σ ω A^{- 1} \approx 421.63963163

. From the proof of Theorem 2, we deduce

Λ_{2} \approx 200146.6802

and

λ_{2} \approx 46123.1544

. Then, by Theorem 2, we conclude that for any

λ \geq λ_{2}

, the problem (28) and (29) with the nonlinearity (31) has at least one positive solution.

5. Conclusions

In this paper, we investigated the existence of positive solutions for the Riemann–Liouville fractional differential Equation (1) with sequential derivatives and a positive parameter, subject to the general nonlocal boundary conditions (2) containing diverse fractional order derivatives and Riemann–Stieltjes integrals. The nonlinearity

f

from (1) can change sign, and it can be singular at

t = 0

and

t = 1

. In the proof of the main results, we used the Guo–Krasnosel’skii fixed point theorem. We also presented the associated Green functions and their properties, and we gave two examples for the illustration of our results.

Author Contributions

Conceptualization, R.L.; formal analysis, A.T. and R.L.; methodology, A.T. and R.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Tudorache, A.; Luca, R. Positive Solutions for a Fractional Differential Equation with Sequential Derivatives and Nonlocal Boundary Conditions. Symmetry 2022, 14, 1779. https://doi.org/10.3390/sym14091779

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Tudorache A, Luca R. Positive Solutions for a Fractional Differential Equation with Sequential Derivatives and Nonlocal Boundary Conditions. Symmetry. 2022; 14(9):1779. https://doi.org/10.3390/sym14091779

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Tudorache, Alexandru, and Rodica Luca. 2022. "Positive Solutions for a Fractional Differential Equation with Sequential Derivatives and Nonlocal Boundary Conditions" Symmetry 14, no. 9: 1779. https://doi.org/10.3390/sym14091779

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Positive Solutions for a Fractional Differential Equation with Sequential Derivatives and Nonlocal Boundary Conditions

Abstract

1. Introduction

2. Auxiliary Results

3. Existence of Positive Solutions

4. Examples

5. Conclusions

Author Contributions

Funding

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Informed Consent Statement

Data Availability Statement

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References

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