Positive solutions for impulsive fractional differential equations with generalizedperiodic boundary value conditions

Zhao, Kaihong; Gong, Ping

doi:10.1186/1687-1847-2014-255

Research
Open access
Published: 29 September 2014

Positive solutions for impulsive fractional differential equations with generalizedperiodic boundary value conditions

Kaihong Zhao¹ &
Ping Gong¹

Advances in Difference Equations volume 2014, Article number: 255 (2014) Cite this article

2188 Accesses
19 Citations
Metrics details

Abstract

By constructing Green’s function, we give the natural formulae of solutions forthe following nonlinear impulsive fractional differential equation with generalizedperiodic boundary value conditions:

{\begin{cases} {}^{c}D_{t}^{q} u (t) = f (t, u (t)), t \in J^{'} = J ∖ {t_{1}, \dots, t_{m}}, J = [0, 1], \\ Δ u (t_{k}) = I (u (t_{k})), Δ u^{'} (t_{k}) = J_{k} (u (t_{k})), k = 1, \dots, m, \\ a u (0) - b u (1) = 0, a u^{'} (0) - b u^{'} (1) = 0, \end{cases}

where $1 < q < 2$ is a real number, ${}^{c}D_{t}^{q}$ is the standard Caputo differentiation. We present theproperties of Green’s function. Some sufficient conditions for the existence ofsingle or multiple positive solutions of the above nonlinear fractional differentialequation are established. Our analysis relies on a nonlinear alternative of theSchauder and Guo-Krasnosel’skii fixed point theorem on cones. As applications,some interesting examples are provided to illustrate the main results.

MSC: 34B10, 34B15, 34B37.

1 Introduction

In recent years, the fractional order differential equation has aroused great attentiondue to both the further development of fractional order calculus theory and theimportant applications for the theory of fractional order calculus in the fields ofscience and engineering such as physics, chemistry, aerodynamics, electrodynamics ofcomplex medium, polymer rheology, Bode’s analysis of feedback amplifiers,capacitor theory, electrical circuits, electron-analytical chemistry, biology, controltheory, fitting of experimental data, and so forth. Many papers and books on fractionalcalculus differential equation have appeared recently. One can see [1–17] and the references therein.

In order to describe the dynamics of populations subject to abrupt changes as well asother phenomena such as harvesting, diseases, and so on, some authors have used animpulsive differential system to describe these kinds of phenomena since the lastcentury. For the basic theory on impulsive differential equations, the reader can referto the monographs of Bainov and Simeonov [18], Lakshmikantham et al.[19] and Benchohra et al.[20].

In this article, we consider the following nonlinear impulsive fractional differentialequation with generalized periodic boundary value conditions (for short BVPs (1.1)):

{\begin{cases} {}^{c}D_{t}^{q} u (t) = f (t, u (t)), t \in J^{'} = J ∖ {t_{1}, \dots, t_{m}}, J = [0, 1], \\ Δ u (t_{k}) = I_{k} (u (t_{k})), Δ u^{'} (t_{k}) = J_{k} (u (t_{k})), k = 1, \dots, m, \\ a u (0) - b u (1) = 0, a u^{'} (0) - b u^{'} (1) = 0, \end{cases}

(1.1)

where a, b are real constants with $a > b > 0$ . ${}^{c}D_{0^{+}}^{q}$ is the Caputo fractional derivative of order $1 < q < 2$ . $f : J \times R^{+} \to R^{+}$ is jointly continuous. $I_{k}, J_{k} \in C (R^{+}, R^{+})$ , $R^{+} = [0, + \infty)$ . The impulsive point set ${t_{k}}_{k = 1}^{m}$ satisfies $0 = t_{0} < t_{1} < \dots < t_{m} < t_{m + 1} = 1$ . $u (t_{k}^{+}) = {lim}_{h \to 0^{+}} u (t_{k} + h)$ and $u (t_{k}^{-}) = {lim}_{h \to 0^{-}} u (t_{k} + h)$ represent the right and left limits of $u (t)$ at the impulsive point $t = t_{k}$ . Let us set $J_{0} = [0, t_{1}]$ , $J_{k} = (t_{k}, t_{k + 1}]$ , $1 \leq k \leq m$ . The goal of this paper is to study the existence ofsingle or multiple positive solutions for the impulsive BVPs (1.1) by a nonlinearalternative of the Schauder and Guo-Krasnosel’skii fixed point theorem oncones.

The rest of the paper is organized as follows. In Section 2, we present some usefuldefinitions, lemmas and the properties of Green’s function. In Section 3, wegive some sufficient conditions for the existence of a single positive solution for BVPs(1.1). In Section 4, some sufficient criteria for the existence of multiplepositive solutions for BVPs (1.1) are obtained. Finally, some examples are provided toillustrate our main results in Section 5.

2 Preliminaries

For the convenience of the reader, we present here the necessary definitions fromfractional calculus theory. These definitions and properties can be found in theliterature.

Definition 2.1 (see [21, 22])

The Riemann-Liouville fractional integral of order $α > 0$ of a function $f : (0, + \infty) \to R$ is given by

I_{0 +}^{α} f (t) = \frac{1}{Γ (α)} \int_{0}^{t} {(t - s)}^{α - 1} f (s) d s,

provided that the right-hand side is pointwise defined on $(0, + \infty)$ .

Definition 2.2 (see [21, 22])

The Caputo fractional derivative of order $α > 0$ of a continuous function $f : (0, + \infty) \to R$ is given by

{}^{c}D_{0 +}^{α} f (t) = \frac{1}{Γ (n - α)} \int_{0}^{t} \frac{f^{(n)} (s)}{{(t - s)}^{α - n + 1}} d s,

where $n - 1 < α \leq n$ , provided that the right-hand side is pointwise defined on $(0, + \infty)$ .

Lemma 2.1 (see [21])

Assume that $u \in C (0, 1) \cap L (0, 1)$ with a Caputo fractional derivative oforder $q > 0$ that belongs to $u \in C^{n} [0, 1]$ , then

I_{0 +}^{q} D_{0 +}^{q} u (t) = u (t) + c_{0} + c_{1} t + \dots + c_{n - 1} t^{n - 1}

for some $c_{i} \in R$ , $i = 0, 1, 2, \dots, n - 1$ ( $n = - [- q]$ ) and $[q]$ denotes the integer part of the real number q.

Lemma 2.2 (see [23])

Let E be a Banach space. Assumethat $T : E \to E$ is a completely continuous operator and theset $V = {u \in E ∣ u = μ T u, 0 < μ < 1}$ is bounded. Then T has a fixedpoint in E.

Lemma 2.3 (Schauder fixed point theorem, see [24])

If U is a close bounded convex subset of a Banachspace E and $T : U \to U$ is completely continuous,then T has at least one fixed point in U.

Lemma 2.4 (see [25])

Let E be a Banach space, $P \subseteq E$ be a cone, and $Ω_{1}$ , $Ω_{2}$ be two bounded open balls of E centeredat the origin with $0 \in Ω_{1}$ and ${\bar{Ω}}_{1} \subset Ω_{2}$ . Suppose that $A : P \cap ({\bar{Ω}}_{2} ∖ Ω_{1}) \to P$ is a completely continuous operator such thateither

(i)
$∥ A u ∥ \leq ∥ u ∥$ , $u \in P \cap \partial Ω_{1}$ and $∥ A u ∥ \geq ∥ u ∥$ , $u \in P \cap \partial Ω_{2}$ , or
(ii)
$∥ A u ∥ \geq ∥ u ∥$ , $u \in P \cap \partial Ω_{1}$ and $∥ A u ∥ \leq ∥ u ∥$ , $u \in P \cap \partial Ω_{2}$

hold. Then A has at least one fixed pointin $P \cap ({\bar{Ω}}_{2} ∖ Ω_{1})$ .

Now we present Green’s function for a system associated with BVPs (1.1).

Lemma 2.5 Given $h \in C (J, R^{+})$ and $1 < q < 2$ , the unique solution of

{\begin{cases} {}^{c}D_{t}^{q} u (t) = h (t), t \in J^{'}, \\ Δ u (t_{k}) = I_{k} (u (t_{k})), Δ u^{'} (t_{k}) = J_{k} (u (t_{k})), k = 1, \dots, m, \\ a u (0) - b u (1) = 0, a u^{'} (0) - b u^{'} (1) = 0, a > b > 0, \end{cases}

(2.1)

is formulated by

u (t) = \int_{0}^{1} G_{1} (t, s) h (s) d s + \sum_{i = 1}^{m} G_{2} (t, t_{i}) J_{i} (u (t_{i})) + \sum_{i = 1}^{m} G_{3} (t, t_{i}) I_{i} (u (t_{i})), t \in J,

where

G_{1} (t, s) = {\begin{cases} \frac{{(t - s)}^{q - 1}}{Γ (q)} + \frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{b (q - 1) t {(1 - s)}^{q - 2}}{(a - b) Γ (q)} + \frac{b^{2} (q - 1) {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)}, & 0 \leq s \leq t \leq 1, \\ \frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{b (q - 1) t {(1 - s)}^{q - 2}}{(a - b) Γ (q)} + \frac{b^{2} (q - 1) {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)}, & 0 \leq t \leq s \leq 1, \end{cases}

(2.2)

G_{2} (t, t_{i}) = {\begin{cases} \frac{a b}{{(a - b)}^{2}} + \frac{a (t - t_{i})}{a - b}, & 0 \leq t_{i} < t \leq 1, i = 1, 2, \dots, m, \\ \frac{a b}{{(a - b)}^{2}} + \frac{b (t - t_{i})}{a - b}, & 0 \leq t \leq t_{i} \leq 1, i = 1, 2, \dots, m, \end{cases}

(2.3)

G_{3} (t, t_{i}) = {\begin{cases} \frac{a}{a - b}, & 0 \leq t_{i} < t \leq 1, i = 1, 2, \dots, m, \\ \frac{b}{a - b}, & 0 \leq t \leq t_{i} \leq 1, i = 1, 2, \dots, m . \end{cases}

(2.4)

Proof Let u be a general solution of (2.1) on each interval $(t_{k}, t_{k + 1}]$ ( $k = 0, 1, \dots, m$ ). Applying Lemma 2.1, Eq. (2.1) is translated intothe following equivalent integral equation (2.5):

u (t) = \frac{1}{Γ (q)} \int_{0}^{t} {(t - s)}^{q - 1} h (s) d s - c_{k} - d_{k} t, \forall t \in (t_{k}, t_{k + 1}],

(2.5)

where $t_{0} = 0$ , $t_{m + 1} = 1$ . Then we have

u^{'} (t) = \frac{1}{Γ (q - 1)} \int_{0}^{t} {(t - s)}^{q - 2} h (s) d s - d_{k}, t \in (t_{k}, t_{k + 1}] .

In the light of the generalized periodic boundary value conditions of Eq. (2.1), we get

b \int_{0}^{1} \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s + a c_{0} - b c_{m} - b d_{m} = 0,

(2.6)

b \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s + a d_{0} - b d_{m} = 0 .

(2.7)

Next, using the right impulsive condition of Eq. (2.1), we derive

c_{k - 1} - c_{k} = I_{k} (u (t_{k})) - J_{k} (u (t_{k})) t_{k},

(2.8)

d_{k - 1} - d_{k} = J_{k} (u (t_{k})) .

(2.9)

By (2.7) and (2.9), we have

d_{0} = \frac{- b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s - \frac{b}{a - b} \sum_{i = 1}^{m} J_{i} (u (t_{i})),

(2.10)

d_{m} = \frac{- b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s - \frac{a}{a - b} \sum_{i = 1}^{m} J_{i} (u (t_{i})) .

(2.11)

By (2.9) we have

\begin{aligned} d_{k} & = d_{0} - \sum_{i = 1}^{k} J_{i} (u (t_{i})) \\ = \frac{- b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s - \frac{b}{a - b} \sum_{i = 1}^{m} J_{i} (u (t_{i})) - \sum_{i = 1}^{k} J_{i} (u (t_{i})) . \end{aligned}

(2.12)

From (2.6), (2.8) and (2.11), we have

\begin{aligned} c_{0} = & \frac{- b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s - \frac{b^{2}}{{(a - b)}^{2}} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s \\ - \frac{a b}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) - \frac{b}{a - b} \sum_{i = 1}^{m} (I_{i} (u (t_{i})) - J_{i} (u (t_{i})) t_{i}) . \end{aligned}

(2.13)

According to (2.8), we obtain

\begin{aligned} c_{k} = & c_{0} - \sum_{i = 1}^{k} (I_{i} (u (t_{i})) - J_{i} (u (t_{i})) t_{i}) \\ = & \frac{- b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s - \frac{b^{2}}{{(a - b)}^{2}} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s \\ - \frac{a b}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) - \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) - \sum_{i = 1}^{k} I_{i} (u (t_{i})) \\ + \frac{b}{a - b} \sum_{i = 1}^{m} J_{i} (u (t_{i})) t_{i} + \sum_{i = 1}^{k} J_{i} (u (t_{i})) t_{i} . \end{aligned}

(2.14)

Hence, for $k = 1, 2, \dots, m$ , (2.12) and (2.14) imply

\begin{aligned} c_{k} + d_{k} t = & \frac{- b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s - \frac{(a b - b^{2}) t + b^{2}}{{(a - b)}^{2}} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s \\ - \frac{1}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) [a b + b (a - b) (t - t_{i})] - \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ - \sum_{i = 1}^{k} I_{i} (u (t_{i})) - \sum_{i = 1}^{k} J_{i} (u (t_{i})) (t - t_{i}) . \end{aligned}

(2.15)

Now substituting (2.10) and (2.13) into (2.5), for $t \in J_{0} = [0, t_{1}]$ , we obtain

\begin{aligned} u (t) = & \int_{0}^{t} \frac{{(t - s)}^{q - 1}}{Γ (q)} h (s) d s + \frac{b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s \\ + \frac{(a b - b^{2}) t + b^{2}}{{(a - b)}^{2}} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s \\ + \frac{1}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) [a b + b (a - b) (t - t_{i})] + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ = & \int_{0}^{t} \frac{{(t - s)}^{q - 1}}{Γ (q)} h (s) d s + \frac{b}{a - b} (\int_{0}^{t} + \int_{t}^{1}) \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s \\ + \frac{(a b - b^{2}) t + b^{2}}{{(a - b)}^{2}} (\int_{0}^{t} + \int_{t}^{1}) \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s \\ + \frac{1}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) [a b + b (a - b) (t - t_{i})] + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ = & \int_{0}^{t} [\frac{{(t - s)}^{q - 1}}{Γ (q)} + \frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{[(a b - b^{2}) t + b^{2}] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q - 1)}] h (s) d s \\ + \int_{t}^{1} [\frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{[(a b - b^{2}) t + b^{2}] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q - 1)}] h (s) d s \\ + \frac{1}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) [a b + b (a - b) (t - t_{i})] + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ = & \int_{0}^{1} G_{1} (t, s) h (s) d s + \sum_{i = 1}^{m} G_{2} (t, t_{i}) J_{i} (u (t_{i})) + \sum_{i = 1}^{m} G_{3} (t, t_{i}) I_{i} (u (t_{i})), \end{aligned}

where $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ and $G_{3} (t, t_{i})$ are defined by (2.2)-(2.4).

Substituting (2.15) into (2.5), for $t \in J_{k} = (t_{k}, t_{k + 1}]$ , $k = 1, 2, \dots, m$ , we have

\begin{aligned} u (t) = & \int_{0}^{t} \frac{{(t - s)}^{q - 1}}{Γ (q)} h (s) d s + \frac{b}{a - b} \int_{0}^{1} \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s \\ + \frac{(a b - b^{2}) t + b^{2}}{{(a - b)}^{2}} \int_{0}^{1} \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s \\ + \frac{1}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) [a b + b (a - b) (t - t_{i})] + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ + \sum_{i = 1}^{k} I_{i} (u (t_{i})) + \sum_{i = 1}^{k} J_{i} (u (t_{i})) (t - t_{i}) \\ = & \int_{0}^{t} \frac{{(t - s)}^{q - 1}}{Γ (q)} h (s) d s + \frac{b}{a - b} (\int_{0}^{t} + \int_{t}^{1}) \frac{{(1 - s)}^{q - 1}}{Γ (q)} h (s) d s \\ + \frac{(a b - b^{2}) t + b^{2}}{{(a - b)}^{2}} (\int_{0}^{t} + \int_{t}^{1}) \frac{{(1 - s)}^{q - 2}}{Γ (q - 1)} h (s) d s \\ + \frac{1}{{(a - b)}^{2}} (\sum_{i = 1}^{k} + \sum_{i = k + 1}^{m}) J_{i} (u (t_{i})) [a b + b (a - b) (t - t_{i})] \\ + \frac{b}{a - b} (\sum_{i = 1}^{k} + \sum_{i = k + 1}^{m}) I_{i} (u (t_{i})) + \sum_{i = 1}^{k} I_{i} (u (t_{i})) + \sum_{i = 1}^{k} J_{i} (u (t_{i})) (t - t_{i}) \\ = & \int_{0}^{t} [\frac{{(t - s)}^{q - 1}}{Γ (q)} + \frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{[(a b - b^{2}) t + b^{2}] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q - 1)}] h (s) d s \\ + \int_{t}^{1} [\frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{[(a b - b^{2}) t + b^{2}] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q - 1)}] h (s) d s \\ + \sum_{i = 1}^{k} [\frac{a b}{{(a - b)}^{2}} + \frac{b (a - b) + {(a - b)}^{2}}{{(a - b)}^{2}} (t - t_{i})] J_{i} (u (t_{i})) \\ + \sum_{i = k + 1}^{m} \frac{a b + b (a - b) (t - t_{i})}{{(a - b)}^{2}} J_{i} (u (t_{i})) + \sum_{i = 1}^{k} [\frac{b}{a - b} + 1] I_{i} (u (t_{i})) \\ + \sum_{i = k + 1}^{m} \frac{b}{a - b} I_{i} (u (t_{i})) \\ = & \int_{0}^{t} [\frac{{(t - s)}^{q - 1}}{Γ (q)} + \frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{[(a b - b^{2}) t + b^{2}] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q - 1)}] h (s) d s \\ + \int_{t}^{1} [\frac{b {(1 - s)}^{q - 1}}{(a - b) Γ (q)} + \frac{[(a b - b^{2}) t + b^{2}] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q - 1)}] h (s) d s \\ + \sum_{i = 1}^{k} \frac{a b + a (a - b) (t - t_{i})}{{(a - b)}^{2}} J_{i} (u (t_{i})) + \sum_{i = k + 1}^{m} \frac{a b + b (a - b) (t - t_{i})}{{(a - b)}^{2}} J_{i} (u (t_{i})) \\ + \sum_{i = 1}^{k} \frac{a}{a - b} I_{i} (u (t_{i})) + \sum_{i = k + 1}^{m} \frac{b}{a - b} I_{i} (u (t_{i})) \\ = & \int_{0}^{1} G_{1} (t, s) h (s) d s + \sum_{i = 1}^{m} G_{2} (t, t_{i}) J_{i} (u (t_{i})) + \sum_{i = 1}^{m} G_{3} (t, t_{i}) I_{i} (u (t_{i})), \end{aligned}

where $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ and $G_{3} (t, t_{i})$ are defined by (2.2)-(2.4). The proof iscomplete. □

Lemma 2.6 Let $0 < b < a < + \infty$ , then Green’sfunctions $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ and $G_{3} (t, t_{i})$ defined by (2.2), (2.3) and (2.4) arecontinuous and satisfy the following:

(i)
$G_{1} (t, s) \in C (J \times J, R^{+})$ , $G_{2} (t, t_{i}), G_{3} (t, t_{i}) \in C (J \times J, R^{+})$ , and $G_{1} (t, s), G_{2} (t, t_{i}), G_{3} (t, t_{i}) > 0$ for all $t, t_{i}, s \in (0, 1)$ , where $J = [0, 1]$ .
(ii)
The functions $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ and $G_{3} (t, t_{i})$ have the following properties:
$\frac{b}{a} M (s) \leq G_{1} (t, s) \leq M (s), \forall t \in J, s \in (0, 1),$
(2.16)

\frac{b^{2}}{{(a - b)}^{2}} \leq G_{2} (t, t_{i}) \leq \frac{a^{2}}{{(a - b)}^{2}}, \forall t, t_{i} \in J,

(2.17)

\frac{b}{a - b} \leq G_{3} (t, t_{i}) \leq \frac{a}{a - b}, \forall t, t_{i} \in J,

(2.18)

where

M (s) = \frac{a [(1 - s) a - (2 - s - q) b] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)} > 0, s \in [0, 1) .

(2.19)

Proof From the expressions of $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ and $G_{3} (t, t_{i})$ , it is obvious that $G_{1} (t, s), G_{2} (t, t_{i}), G_{3} (t, t_{i}) \in C (J \times J, R^{+})$ and $G_{1} (t, s), G_{2} (t, t_{i}), G_{3} (t, t_{i}) > 0$ for all $t, t_{i}, s \in (0, 1)$ . Next, we will prove (ii). From the definition of $G_{1} (t, s)$ , we can know that, for given $s \in (0, 1)$ , $G_{1} (t, s)$ is increasing with respect to t for $t \in J$ . We let

\begin{matrix} g_{1} (t, s) = \frac{{(a - b)}^{2} {(t - s)}^{q - 1} + [(a - b) (1 - s) + [(a - b) t + b] (q - 1)] b {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)}, t \in [s, 1], \\ g_{2} (t, s) = \frac{[(a - b) (1 - s) + [(a - b) t + b] (q - 1)] b {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)}, t \in [0, s] . \end{matrix}

Hence, we derive

\begin{matrix} \begin{aligned} min_{t \in [0, 1]} G_{1} (t, s) & = min {min_{t \in [s, 1]} g_{1} (t, s), min_{t \in [0, s]} g_{2} (t, s)} = min {g_{1} (s, s), g_{2} (0, s)} = g_{2} (0, s) \\ = \frac{[(a - b) (1 - s) + b (q - 1)] b {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)} \\ = \frac{b [(1 - s) a - (2 - s - q) b] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)} ≜ m (s), s \in [0, 1), \end{aligned} \\ \begin{aligned} max_{t \in [0, 1]} G_{1} (t, s) & = max {max_{t \in [s, 1]} g_{1} (t, s), max_{t \in [0, s]} g_{2} (t, s)} = max {g_{1} (1, s), g_{2} (s, s)} = g_{1} (1, s) \\ = \frac{[(a - b) (1 - s) + b (q - 1)] a {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)} \\ = \frac{a [(1 - s) a - (2 - s - q) b] {(1 - s)}^{q - 2}}{{(a - b)}^{2} Γ (q)} ≜ M (s), s \in [0, 1) . \end{aligned} \end{matrix}

Thus, we have

\frac{b}{a} M (s) = m (s) \leq G_{1} (t, s) \leq M (s) .

It is obvious that

\frac{b^{2}}{{(a - b)}^{2}} = G_{2} (0, 1) \leq G_{2} (t, t_{i}) \leq G_{2} (1, 0) = \frac{a^{2}}{{(a - b)}^{2}}, \frac{b}{a - b} \leq G_{3} (t, t_{i}) \leq \frac{a}{a - b} .

The proof is completed. □

3 Existence of single positive solutions

In this section, we discuss the existence of positive solutions for BVP (1.1).

Let $E = {u (t) : u (t) \in C (J)}$ denote a real Banach space with the norm $∥ \cdot ∥$ defined by $∥ u ∥ = {max}_{t \in J} | u (t) |$ . Let

\begin{matrix} \begin{aligned} P C (J) = & {u \in E ∣ u : J \to R^{+}, u \in C (J^{'}), u (t_{k}^{-}) and u (t_{k}^{+}) \\ exist with u (t_{k}^{-}) = u (t_{k}), 1 \leq k \leq m}, \end{aligned} \\ K = {u \in P C (J) : u (t) \geq \frac{b^{2}}{a^{2}} ∥ u ∥, t \in J}, \end{matrix}

(3.1)

K_{r} = {u \in K : ∥ u ∥ < r}, \partial K_{r} = {u \in K : ∥ u ∥ = r} .

(3.2)

Obviously, $P C (J) \subset E$ is a Banach space with the norm $∥ u ∥ = {max}_{t \in J} | u (t) |$ . $K \subset P C (J)$ is a positive cone.

In the following, we need the assumptions and some notations as follows:

(B₁) $0 < b < a < 1$ , $0 < σ_{1}, σ_{2} < + \infty$ , where $σ_{1} = \int_{0}^{1} M (s) d s$ , $σ_{2} = \frac{b^{3}}{a^{3}} \int_{0}^{1} M (s) d s$ .

(B₂) $f \in C (J \times R^{+}, R^{+})$ and $f (t, 0) = 0$ for all $t \in J$ .

(B₃) $I_{k} (u (t_{k})), J_{k} (u (t_{k})) \in C (R^{+}, R^{+})$ , $k = 1, 2, \dots, m$ .

Let

\begin{aligned} \bar{N} = max {\frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})), \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i}))}, \\ f^{δ} = \underset{u \to δ}{lim sup} max_{t \in J} \frac{f (t, u)}{u}, f_{δ} = \underset{u \to δ}{lim inf} min_{t \in J} \frac{f (t, u)}{u}, \end{aligned}

where δ denotes 0 or +∞. In addition, we introduce the followingweight functions:

\begin{aligned} Φ (r) = max {f (t, u (t)) : (t, u) \in [0, 1] \times [\frac{b^{2}}{a^{2}} r, r]}, \\ ϕ (r) = min {f (t, u (t)) : (t, u) \in [0, 1] \times [\frac{b^{2}}{a^{2}} r, r]} . \end{aligned}

From Lemma 2.4, we can obtain the following lemma.

Lemma 3.1 Suppose that $f (t, u)$ is continuous,then $u \in P C (J)$ is a solution of BVPs (1.1) if and onlyif $u \in P C (J)$ is a solution of the integral equation

u (t) = \int_{0}^{1} G_{1} (t, s) f (s, u (s)) d s + \sum_{i = 1}^{m} G_{2} (t, t_{i}) J_{i} (u (t_{i})) + \sum_{i = 1}^{m} G_{3} (t, t_{i}) I_{i} (u (t_{i})), \forall t \in J .

Define $T : P C (J) \to P C (J)$ to be the operator defined as

(T u) (t) = \int_{0}^{1} G_{1} (t, s) f (s, u (s)) d s + \sum_{i = 1}^{m} G_{2} (t, t_{i}) J_{i} (u (t_{i})) + \sum_{i = 1}^{m} G_{3} (t, t_{i}) I_{i} (u (t_{i})) .

(3.3)

Then, by Lemma 3.1, the existence of solutions for BVPs (1.1) is translated intothe existence of the fixed point for $u = T u$ , where T is given by (3.3). Thus, the fixed pointof the operator T coincides with the solution of problem (1.1).

Lemma 3.2 Assume that (B₁)-(B₃) hold,then $T : P C (J) \to P C (J)$ and $T : K \to K$ defined by (3.3) are completelycontinuous.

Proof Firstly, we shall show that $T : P C (J) \to P C (J)$ is completely continuous through three steps.

Step 1. Let $u \in P C (J)$ , in view of the nonnegativity and continuity of functions $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ , $G_{3} (t, t_{i})$ , $f (t, u (t))$ , $I_{k}$ , $J_{k}$ and $a > b > 0$ , we conclude that $T : P C (J) \to P C (J)$ is continuous.

Step 2. We will prove that T maps bounded sets into bounded sets. Indeed, it isenough to show that for any $r > 0$ there exists a positive constant L such that, foreach $u \in Ω_{r} = {u \in P C (J) : ∥ u ∥ \leq r}$ , $∥ T u ∥ \leq L$ when $| f (t, u) | \leq l_{1}$ , $| J_{k} | \leq l_{2}$ , $| I_{k} | \leq l_{3}$ , where $l_{i}$ ( $i = 1, 2, 3$ ) are some fixed positive constants. In fact, for each $t \in J_{k}$ , $u \in Ω_{r}$ , $k = 0, 1, 2, \dots, m$ , by Lemma 2.5, we have

\begin{aligned} | (T u) (t) | & \leq \int_{0}^{1} | G_{1} (t, s) f (s, u (s)) | d s + \sum_{i = 1}^{m} | G_{2} (t, t_{i}) J_{i} (u (t_{i})) | + \sum_{i = 1}^{m} | G_{3} (t, t_{i}) I_{i} (u (t_{i})) | \\ \leq σ_{1} l_{1} + \frac{a^{2} m l_{2}}{{(a - b)}^{2}} + \frac{a m l_{3}}{a - b} ≜ L, \end{aligned}

which imply that $∥ T u ∥ \leq L$ .

Step 3. T is equicontinuous. In fact, since $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ , $G_{3} (t, t_{i})$ are continuous on $J \times J$ , they are uniformly continuous on $J \times J$ . Thus, for fixed $s \in J$ and for any $ε > 0$ , there exists a constant $δ > 0$ such that for any $t_{1}, t_{2} \in J_{k}$ with $| t_{1} - t_{2} | < δ$ , $0 \leq k \leq m$ , we have

\begin{aligned} | G_{1} (t_{1}, s) - G_{2} (t_{2}, s) | < \frac{ε}{3 l_{1}}, | G_{2} (t_{1}, t_{i}) - G_{2} (t_{2}, t_{i}) | < \frac{ε}{3 m l_{2}}, \\ | G_{3} (t_{1}, t_{i}) - G_{3} (t_{2}, t_{i}) | < \frac{ε}{3 m l_{3}} . \end{aligned}

Then

\begin{aligned} | T u (t_{2}) - T u (t_{1}) | \\ = | \int_{0}^{1} (G_{1} (t_{2}, s) - G_{1} (t_{1}, s)) f (s, u (s)) d s + \sum_{i = 1}^{m} (G_{2} (t_{2}, t_{i}) - G_{2} (t_{1}, t_{i})) J_{i} (u (t_{i})) \\ + \sum_{i = 1}^{m} (G_{3} (t_{2}, t_{i}) - G_{3} (t_{1}, t_{i})) I_{i} (u (t_{i})) | \\ \leq l_{1} \int_{0}^{1} | G_{1} (t_{2}, s) - G_{2} (t_{1}, s) | d s + m l_{2} | G_{2} (t_{2}, t_{i}) - G_{2} (t_{1}, t_{i}) | \\ + m l_{3} | G_{3} (t_{2}, t_{i}) - G_{3} (t_{1}, t_{i}) | \\ < \frac{ε}{3} + \frac{ε}{3} + \frac{ε}{3} = ε, \end{aligned}

which means that $T (Ω_{r})$ is equicontinuous on all the subintervals $t \in J_{k}$ , $k = 0, 1, \dots, m$ . Thus, by means of the Arzela-Ascoli theorem, we have that $T : P C (J) \to P C (J)$ is completely continuous.

Next, we will show that $T : K \to K$ is completely continuous. Indeed, for each $t \in J_{k}$ , every $u \in C (J_{k}, R^{+})$ , $k = 0, 1, 2, \dots, m$ , Lemma 2.5 implies that

(T u) (t) \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{b^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) .

On the other hand,

∥ T u ∥ = max_{t \in J_{k}} (T u) (t) \leq \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) .

Thus,

\begin{aligned} \frac{b^{2}}{a^{2}} ∥ T u ∥ & = \frac{b^{2}}{a^{2}} max_{t \in J_{k}} (T u) (t) \\ \leq \frac{b^{2}}{a^{2}} \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{b^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{b^{2}}{a (a - b)} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \leq (T u) (t) . \end{aligned}

So $(T u) (t) \geq \frac{b^{2}}{a^{2}} ∥ T u ∥$ for every $u \in C (J, R^{+})$ , which implies $T (K) \subset K$ . Similar to the above arguments, we can easily concludethat $T : K \to K$ is a completely continuous operator. The proof iscomplete. □

Theorem 3.1 Assume that (B₁)-(B₃) hold,and suppose that the following assumptions hold:

(A₁) There exists a constant $L_{1} > 0$ such that $| f (t, u) - f (t, v) | \leq L_{1} | u - v |$ for each $t \in J$ and all $u, v \in R^{+}$ .

(A₂) There exists a constant $L_{2} > 0$ such that $| J_{k} (u) - J_{k} (v) | \leq L_{2} | u - v |$ for all $u, v \in R^{+}$ , $k = 1, 2, \dots, m$ .

(A₃) There exists a constant $L_{3} > 0$ such that $| I_{k} (u) - I_{k} (v) | \leq L_{3} | u - v |$ for all $u, v \in R^{+}$ , $k = 1, 2, \dots, m$ .

If $ρ = σ_{1} L_{1} + \frac{m a^{2} L_{2}}{{(a - b)}^{2}} + \frac{m a L_{3}}{a - b} < 1$ , then problem (1.1) has a unique solutionin $K_{ρ}$ .

Proof Let the operator $T : K_{ρ} \to K_{ρ}$ be defined by (3.3). For all $u, v \in K_{ρ}$ , from Lemma 2.5, we obtain

\begin{aligned} | (T u) (t) - (T v) (t) | \\ \leq \int_{0}^{1} G_{1} (t, s) | f (s, u (s)) - f (s, v (s)) | d s \\ + \sum_{i = 1}^{m} G_{2} (t, t_{i}) | J_{i} (u (t_{i})) - J_{i} (v (t_{i})) | + \sum_{i = 1}^{m} G_{3} (t, t_{i}) | I_{i} (u (t_{i})) - I_{i} (v (t_{i})) | \\ \leq σ_{1} L_{1} ∥ u - v ∥ + \frac{m a^{2} L_{2}}{{(a - b)}^{2}} ∥ u - v ∥ + \frac{m a L_{3}}{a - b} ∥ u - v ∥ = ρ ∥ u - v ∥, \end{aligned}

where $ρ = σ_{1} L_{1} + \frac{m a^{2} L_{2}}{{(a - b)}^{2}} + \frac{m a L_{3}}{a - b} < 1$ . Consequently, T is a contraction mapping.Moreover, from Lemma 3.2, T is completely continuous. Therefore, by theBanach contraction map principle, the operator T has a unique fixed point in $K_{ρ}$ which is the unique positive solution of system (1.1).This completes the proof. □

Theorem 3.2 Assume that (B₁)-(B₃) hold,and suppose that the following assumptions hold:

(A₄) There exists a constant $N_{1} > 0$ such that $| f (t, u) | \leq N_{1}$ for each $t \in J$ and all $u \in R^{+}$ .

(A₅) There exists a constant $N_{2} > 0$ such that $| J_{k} (u) | \leq N_{2}$ for all $u \in R^{+}$ , $k = 1, 2, \dots, m$ .

(A₆) There exists a constant $N_{3} > 0$ such that $| I_{k} (u) | \leq N_{3}$ for all $u \in R^{+}$ , $k = 1, 2, \dots, m$ .

Then BVPs (1.1) have at least one positive solutionin $P C (J)$ .

Proof Let $T : P C (J) \to P C (J)$ be cone preserving completely continuous that is definedby (3.3). According to Lemma 2.2, now it remains to show that the set

Ω = {u \in P C (J) ∣ u = λ T u for some 0 < λ < 1}

(3.4)

is bounded.

Let $u \in Ω$ , then $u = λ T u$ for some $0 < λ < 1$ . Thus, by Lemma 2.5, for each $t \in J_{k}$ , $k = 0, 1, \dots, m$ , we have

\begin{aligned} | u (t) | & = | λ T u | \\ \leq \int_{0}^{1} | G_{1} (t, s) f (s, u (s)) | d s + \sum_{i = 1}^{m} | G_{2} (t, t_{i}) J_{i} (u (t_{i})) | + \sum_{i = 1}^{m} | G_{3} (t, t_{i}) I_{i} (u (t_{i})) | \\ \leq σ_{1} N_{1} + \frac{a^{2} m N_{2}}{{(a - b)}^{2}} + \frac{a m N_{3}}{a - b} . \end{aligned}

Thus, for every $t \in J$ , we have $∥ u (t) ∥ \leq σ_{1} N_{1} + \frac{a^{2} m N_{2}}{{(a - b)}^{2}} + \frac{a m N_{3}}{a - b}$ , which indicates that the set Ω is bounded. Accordingto Lemma 2.2, T has a fixed point $u \in P C (J)$ . Therefore, BVPs (1.1) have at least one positivesolution. The proof is complete. □

In the following, we present an existence result when the nonlinearity and the impulsefunctions have sublinear growth.

Theorem 3.3 Assume that (B₁)-(B₃) hold andsuppose that the following assumptions hold:

(A₇) There exist $a_{1} \in P C (J)$ , $b_{1} > 0$ and $α \in [0, 1)$ such that $| f (t, u) | \leq a_{1} (t) + b_{1} {| u |}^{α}$ for each $t \in J$ and all $u \in R^{+}$ .

(A₈) There exist constants $a_{2}, b_{2} > 0$ and $α \in [0, 1)$ such that $| J_{k} (u) | \leq a_{2} + b_{2} {| u |}^{α}$ for all $u \in R^{+}$ , $k = 1, 2, \dots, m$ .

(A₉) There exist constants $a_{3}, b_{3} > 0$ and $α \in [0, 1)$ such that $| I_{k} (u) | \leq a_{3} + b_{3} {| u |}^{α}$ for all $u \in R^{+}$ , $k = 1, 2, \dots, m$ .

(A₁₀) $b^{*} < 1$ , $a^{*} + b^{*} \geq 1$ , where $a^{*} = p σ_{1} + \frac{a^{2} m a_{2}}{{(a - b)}^{2}} + \frac{a m a_{3}}{a - b}$ , $b^{*} = b_{1} σ_{1} + \frac{a^{2} m b_{2}}{{(a - b)}^{2}} + \frac{a m b_{3}}{a - b}$ .

Then BVPs (1.1) have at least one positive solutionin $P C (J)$ .

Proof Let $T : P C (J) \to P C (J)$ and Ω be defined by (3.3) and (3.4), respectively.Denote $p = {max}_{t \in J} | a_{1} (t) |$ . If $u \in Ω$ , then for $t \in J$ we have

\begin{aligned} | u (t) | = & | λ T u | \\ \leq & \int_{0}^{1} | G_{1} (t, s) (a_{1} (s) + b_{1} {| u (s) |}^{α}) | d s + \sum_{i = 1}^{m} | G_{2} (t, t_{i}) (a_{2} + b_{2} {| u |}^{α}) | \\ + \sum_{i = 1}^{m} | G_{3} (t, t_{i}) (a_{3} + b_{3} {| u |}^{α}) | \\ \leq & p \int_{0}^{1} M (s) d s + b_{1} {∥ u ∥}^{α} \int_{0}^{1} M (s) d s + \frac{a^{2} m (a_{2} + b_{2} {∥ u ∥}^{α})}{{(a - b)}^{2}} + \frac{a m (a_{3} + b_{3} {∥ u ∥}^{α})}{a - b} \\ = & a^{*} + b^{*} {∥ u ∥}^{α}, \end{aligned}

which imply that $∥ u ∥ \leq a^{*} + b^{*} {∥ u ∥}^{α}$ . When $0 < ∥ u ∥ \leq 1$ , then $∥ u ∥ \leq a^{*} + b^{*}$ . When $∥ u ∥ > 1$ , then $∥ u ∥ \leq \frac{a^{*}}{1 - b^{*}}$ . Taking $C = max {a^{*} + b^{*}, \frac{a^{*}}{1 - b^{*}},}$ , we have $∥ u ∥ \leq C$ for any solution of (3.4). This shows that the set Ωis bounded. According to Lemma 2.2, T has at least one fixed point in $P C (J)$ . Therefore, BVPs (1.1) have at least one positive solutionin $P C (J)$ . The proof is complete. □

Theorem 3.4 Assume that (B₁)-(B₃) hold.And suppose that one of the following conditions is satisfied:

(H₁) $f^{\infty} < \frac{1}{σ_{1}}$ (particularly, $f^{\infty} = 0$ ).

(H₂) There exists a constant $M > 0$ such that $f (t, u) \leq \frac{M}{σ_{1}}$ for $t \in J$ , $u \in [M, + \infty)$ .

(H₃) There exists a constant $N > 0$ such that $Φ (N) \leq \frac{N}{3 σ_{1}}$ for $t \in J$ , $u \in [\frac{b^{2}}{a^{2}} N, N]$ .

Then BVPs (1.1) have at least one positive solution.

Proof Case 1. Considering $f^{\infty} < \frac{1}{σ_{1}}$ , there exists ${\bar{r}}_{1} > 0$ such that $f (t, u) \leq (f^{\infty} + ε_{1}) u$ for all $u \in ({\bar{r}}_{1}, + \infty)$ , $t \in J$ , where $ε_{1}$ satisfies $σ_{1} (f^{\infty} + ε_{1}) \leq 1$ .

Choose $r_{1} > max {{\bar{r}}_{1}, 2 \bar{N} {(1 - σ_{1} (f^{\infty} + ε_{1}))}^{- 1}}$ , let $u \in Ω_{1} ≜ K_{r_{1}}$ . We can easily know that $Ω_{1}$ is a close bounded convex subset of a Banach space $P C (J)$ . Then, for $t \in J$ , $u \in Ω_{1}$ , in view of the nonnegativity and continuity of functions $G_{1} (t, s)$ , $G_{2} (t, t_{i})$ , $G_{3} (t, t_{i})$ , $f (t, u (t))$ , $I_{k}$ , $J_{k}$ and $a > b > 0$ , we conclude that $T u \in P$ , $T u \geq 0$ , $t \in J$ . By Lemma 2.5, we can obtain the followinginequality:

\begin{aligned} \frac{b^{2}}{a^{2}} ∥ T u ∥ & = \frac{b^{2}}{a^{2}} max_{t \in J} (T u) (t) \\ \leq \frac{b^{2}}{a^{2}} [\int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i}))] \\ \leq \frac{b^{2}}{a^{2}} [\int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i}))] \\ \leq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{b^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \leq (T u) (t), t \in J . \end{aligned}

Thus $T u \in K$ .

Next, we prove $∥ T u ∥ \leq r_{1}$ . Indeed, for $t \in J$ , $u \in \partial K_{r_{1}}$ , we get

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \leq \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \leq \int_{0}^{1} M (s) (f^{\infty} + ε_{1}) u (s) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \leq σ_{1} (f^{\infty} + ε_{1}) ∥ u ∥ + 2 \bar{N} \\ < σ_{1} (f^{\infty} + ε_{1}) r_{1} + r_{1} - σ_{1} (f^{\infty} + ε_{1}) r_{1} = r_{1} . \end{aligned}

Therefore, $T (Ω_{1}) \subset Ω_{1}$ . From Lemma 3.2, we have that $T : Ω_{1} \to Ω_{1}$ is completely continuous. Thus BVPs (1.1) have at least apositive solution by Lemma 2.3.

Case 2. Condition (H₂) holds. Let $u \in Ω_{2} ≜ K_{d}$ , where $d > 0$ satisfies $d \geq 1 + M + σ_{1} {max}_{t \in J, u \in [0, M]} f (t, u) + 2 \bar{N}$ . By the ways of Case 1, we can also get $T u \in K$ . Now we prove $∥ T u ∥ \leq d$ . In fact,

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \leq \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \leq \int_{s \in J, u (s) > M} M (s) f (s, u (s)) d s + \int_{s \in J, 0 \leq u (s) \leq M} M (s) f (s, u (s)) d s + 2 \bar{N} \\ \leq \int_{0}^{1} M (s) \frac{M}{σ_{1}} d s + \int_{0}^{1} M (s) d s max_{t \in J, u \in [0, M]} f (t, u) + 2 \bar{N} \\ = M + σ_{1} max_{t \in J, u \in [0, M]} f (t, u) + 2 \bar{N} < d . \end{aligned}

Therefore, $T (Ω_{2}) \subset Ω_{2}$ . From Lemma 3.2 we have that $T : Ω_{2} \to Ω_{2}$ is completely continuous. Thus BVPs (1.1) have at least apositive solution by Lemma 2.3.

Case 3. Condition (H₃) holds. Let $u \in Ω_{3} ≜ K_{N}$ , where $N > 0$ satisfies $N \geq 3 \bar{N}$ , we get $\frac{b^{2}}{a^{2}} ∥ u ∥ \leq u (t) \leq ∥ u ∥$ . By the ways of Case 1, we can also get $T u \in K$ . Now we prove $∥ T u ∥ \leq N$ . By assumption (H₃), we have

f (t, u) \leq Φ (N) \leq \frac{N}{3 σ_{1}}, \forall t \in J, u \in [\frac{b^{2}}{a^{2}} N, N] .

In view of Lemma 2.6, we have

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \leq \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \leq \int_{0}^{1} M (s) \frac{N}{3 σ_{1}} d s + 2 \bar{N} \\ \leq \frac{N}{3} + \frac{2 N}{3} = N . \end{aligned}

Therefore, $T (Ω_{3}) \subset Ω_{3}$ . From Lemma 3.2 we have $T : Ω_{3} \to Ω_{3}$ is completely continuous. Thus BVPs (1.1) have at least apositive solution by Lemma 2.3. We complete the proof ofTheorem 3.4. □

4 Existence of multiple positive solutions

In this section, we discuss the multiplicity of positive solutions for BVPs (1.1) by theGuo-Krasnoselskii fixed point theorem.

Theorem 4.1 Assume that (B₁)-(B₃) hold,and suppose that the following two conditions are satisfied:

(H₄) $f_{0} > \frac{1}{σ_{2}}$ and $f_{\infty} > \frac{1}{σ_{2}}$ (particularly, $f_{0} = f_{\infty} = \infty$ ).

(H₅) There exists a constant $c \geq 3 \bar{N}$ such that $Φ (c) < \frac{c}{3 σ_{1}}$ for $t \in J$ , $u \in [\frac{b^{2}}{a^{2}} c, c]$ .

Then for BVPs (1.1) there exist at least two positivesolutions $u_{1}$ , $u_{2}$ , which satisfy

0 < ∥ u_{1} ∥ < c < ∥ u_{2} ∥ .

(4.1)

Proof Choose r, R with $0 < r < c < R$ . Considering $f_{0} > \frac{1}{σ_{2}}$ , there exists $r > 0$ such that $f (t, u) \geq (f_{0} - ε_{2}) u$ for $t \in J$ , $u \in [0, r]$ , where $ε_{2} > 0$ satisfies $(f_{0} - ε_{2}) σ_{2} \geq 1$ . Then, for $u \in \partial K_{r}$ , $t \in J$ , we have

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{b^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s \geq \frac{b}{a} \int_{0}^{1} M (s) (f_{0} - ε_{2}) u (s) d s \\ \geq \frac{b}{a} \int_{0}^{1} M (s) (f_{0} - ε_{2}) \frac{b^{2}}{a^{2}} ∥ u ∥ d s \\ = (f_{0} - ε_{2}) σ_{2} ∥ u ∥ \geq ∥ u ∥ . \end{aligned}

Therefore,

∥ T u ∥ \geq ∥ u ∥, u \in \partial K_{r} .

(4.2)

Considering $f_{\infty} > \frac{1}{σ_{2}}$ , there exists $R > 0$ such that $f (t, u) \geq (f_{\infty} - ε_{3}) u$ for $t \in J$ , $u \in [R, \infty)$ , where $ε_{3} > 0$ satisfies $(f_{\infty} - ε_{3}) σ_{2} \geq 1$ . Then, for $u \in \partial K_{R}$ , $t \in J$ , we have

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{b^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s \geq \frac{b}{a} \int_{0}^{1} M (s) (f_{\infty} - ε_{3}) u (s) d s \\ \geq \frac{b}{a} \int_{0}^{1} M (s) (f_{\infty} - ε_{3}) \frac{b^{2}}{a^{2}} ∥ u ∥ d s = (f_{\infty} - ε_{3}) σ_{2} ∥ u ∥ \geq ∥ u ∥ . \end{aligned}

So

∥ T u ∥ \geq ∥ u ∥, u \in \partial K_{R} .

(4.3)

On the other hand, by assumption (H₅), we have

f (t, u) \leq Φ (c) < \frac{c}{3 σ_{1}}, for t \in J, u \in [\frac{b^{2}}{a^{2}} c, c] .

For $u \in \partial K_{c}$ , where $c > 0$ satisfies $c \geq 3 \bar{N}$ . In view of Lemma 2.6, we have

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \leq \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ < \int_{0}^{1} M (s) \frac{c}{3 σ_{1}} d s + 2 \bar{N} \leq \frac{c}{3} + \frac{2 c}{3} = c = ∥ u ∥ . \end{aligned}

Therefore,

∥ T u ∥ < ∥ u ∥, u \in \partial K_{c} .

(4.4)

Thus, applying Lemma 2.4 to (4.2)-(4.4) yields that T has the fixed point $u_{1} \in K \cap ({\bar{K}}_{c} ∖ K_{r})$ and the fixed point $u_{2} \in K \cap ({\bar{K}}_{R} ∖ K_{c})$ . Thus it follows that problem (1.1) has at least twopositive solutions $u_{1}$ and $u_{2}$ . Noticing (4.4), we have $∥ u_{1} ∥ \neq c$ and $∥ u_{2} ∥ \neq c$ . Therefore (4.1) holds. The proof iscomplete. □

Theorem 4.2 Assume that (B₁)-(B₃) hold.Further suppose that there exist three positivenumbers $ξ_{i}$ ( $i = 1, 2, 3$ ) with $3 \bar{N} \leq ξ_{1} < ξ_{2} < ξ_{3}$ such that one of the following conditions issatisfied:

(H₆) $ϕ (ξ_{1}) \geq \frac{ξ_{1}}{σ_{2}}$ , $Φ (ξ_{2}) \leq \frac{ξ_{2}}{3 σ_{1}}$ , $ϕ (ξ_{3}) \geq \frac{ξ_{3}}{σ_{2}}$ .

(H₇) $Φ (ξ_{1}) \leq \frac{ξ_{1}}{3 σ_{1}}$ , $ϕ (ξ_{2}) > \frac{ξ_{2}}{σ_{2}}$ , $Φ (ξ_{3}) \leq \frac{ξ_{3}}{3 σ_{1}}$ .

Then BVPs (1.1) have at least two positivesolutions $u_{1}$ , $u_{2}$ with

ξ_{1} \leq ∥ u_{1} ∥ < ξ_{2} < ∥ u_{2} ∥ \leq ξ_{3} .

(4.5)

Proof Because the proofs are similar, we prove only case (H₆).Considering $ϕ (ξ_{1}) \geq \frac{ξ_{1}}{σ_{2}}$ , we have $f (t, u) \geq ϕ (ξ_{1}) \geq \frac{ξ_{1}}{σ_{2}}$ for $t \in J$ , $u \in [\frac{b^{2}}{a^{2}} ξ_{1}, ξ_{1}]$ . Then, for $u \in \partial K_{ξ_{1}}$ , $t \in J$ , we have

\begin{aligned} | T u ∥ & = max_{t \in J} (T u) (t) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{b^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s \geq \frac{b}{a} \int_{0}^{1} M (s) \frac{ξ_{1}}{σ_{2}} d s \\ \geq \frac{b^{3}}{a^{3}} \int_{0}^{1} M (s) d s \frac{ξ_{1}}{σ_{2}} = ξ_{1} = ∥ u ∥ . \end{aligned}

Therefore,

∥ T u ∥ \geq ∥ u ∥, u \in \partial K_{ξ_{1}} .

(4.6)

Considering $Φ (ξ_{2}) \leq \frac{ξ_{2}}{3 σ_{1}}$ , we have $f (t, u) \leq Φ (ξ_{2}) \leq \frac{ξ_{2}}{3 σ_{1}}$ for $t \in J$ , $u \in [\frac{b^{2}}{a^{2}} ξ_{2}, ξ_{2}]$ . Then, for $u \in \partial K_{ξ_{2}}$ , $t \in J$ , we derive

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \leq \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{a^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{a}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \leq \int_{0}^{1} M (s) \frac{ξ_{2}}{3 σ_{1}} d s + 2 \bar{N} \leq \frac{ξ_{2}}{3} + \frac{2 ξ_{1}}{3} < \frac{ξ_{2}}{3} + \frac{2 ξ_{2}}{3} = ξ_{2} = ∥ u ∥ . \end{aligned}

So,

∥ T u ∥ < ∥ u ∥, u \in \partial K_{ξ_{2}} .

(4.7)

Considering $ϕ (ξ_{3}) \geq \frac{ξ_{3}}{σ_{2}}$ , we have $f (t, u) \geq ϕ (ξ_{3}) \geq \frac{ξ_{3}}{σ_{2}}$ for $t \in J$ , $u \in [\frac{b^{2}}{a^{2}} ξ_{3}, ξ_{3}]$ . Then, for $u \in \partial K_{ξ_{3}}$ , $t \in J$ , we have

\begin{aligned} ∥ T u ∥ & = max_{t \in J} (T u) (t) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s + \frac{b^{2}}{{(a - b)}^{2}} \sum_{i = 1}^{m} J_{i} (u (t_{i})) + \frac{b}{a - b} \sum_{i = 1}^{m} I_{i} (u (t_{i})) \\ \geq \frac{b}{a} \int_{0}^{1} M (s) f (s, u (s)) d s \geq \frac{b}{a} \int_{0}^{1} M (s) \frac{ξ_{3}}{σ_{2}} d s \geq \frac{b^{3}}{a^{3}} \int_{0}^{1} M (s) d s \frac{ξ_{3}}{σ_{2}} = ξ_{3} = ∥ u ∥ . \end{aligned}

Therefore,

∥ T u ∥ \geq ∥ u ∥, u \in \partial K_{ξ_{3}} .

(4.8)

Thus, applying Lemma 2.4 to (4.6)-(4.8) yields that T has the fixed point $u_{1} \in K \cap ({\bar{K}}_{ξ_{2}} ∖ K_{ξ_{1}})$ and the fixed point $u_{2} \in K \cap ({\bar{K}}_{ξ_{3}} ∖ K_{ξ_{2}})$ . Thus it follows that BVPs (1.1) have at least twopositive solutions $u_{1}$ and $u_{2}$ . Noticing (4.7), we have $∥ u_{1} ∥ \neq ξ_{2}$ and $∥ u_{2} ∥ \neq ξ_{2}$ . Therefore (4.5) holds. The proof iscomplete. □

Similar to the above proof, we can obtain the general theorem.

Theorem 4.3 Assume that (B₁)-(B₃) hold.Suppose that there exist $n + 1$ positive numbers $ξ_{i}$ ( $i = 1, 2, \dots, n + 1$ ) with $3 \bar{N} \leq ξ_{1} < ξ_{2} < \dots < ξ_{n + 1}$ such that one of the following conditions issatisfied:

(H₈) $ϕ (ξ_{2 j - 1}) > \frac{ξ_{2 j - 1}}{σ_{2}}$ , $Φ (ξ_{2 j}) < \frac{ξ_{2 j}}{3 σ_{1}}$ , $j = 1, 2, \dots, [\frac{n + 2}{2}]$ ;

(H₉) $Φ (ξ_{2 j - 1}) < \frac{ξ_{2 j - 1}}{3 σ_{1}}$ , $ϕ (ξ_{2 j}) > \frac{ξ_{2 j}}{σ_{2}}$ , $j = 1, 2, \dots, [\frac{n + 2}{2}]$ .

Then BVPs (1.1) have at least n positivesolutions $u_{i}$ ( $i = 1, 2, \dots, n$ ) with

ξ_{i} < ∥ u_{i} ∥ < ξ_{i + 1} .

(4.9)

5 Illustrative examples

Example 5.1 Consider the BVPs of impulsive nonlinear fractional orderdifferential equations:

{\begin{cases} {}^{c}D_{t}^{q} u (t) = f (t, u (t)), t \in J, t \neq \frac{1}{2}, \\ Δ u (\frac{1}{2}) = I (u (\frac{1}{2})), Δ u^{'} (\frac{1}{2}) = J (u (\frac{1}{2})), \\ a u (0) - b u (1) = 0, a u^{'} (0) - b u^{'} (1) = 0 . \end{cases}

(5.1)

If we let $q = \frac{3}{2}$ , $a = 2$ , $b = 1$ , $f (t, u) = \frac{Γ (\frac{3}{2}) cos t}{{(t + 2 \sqrt{5})}^{2}} \frac{u (t)}{1 + u (t)}$ , $(t, u) \in [0, 1] \times [0, \infty)$ , $I (u) = \frac{u}{5 + u}$ , $J (u) = \frac{u}{10 + u}$ , $u \in [0, \infty)$ .

For $u, v \in [0, \infty)$ , $t \in [0, 1]$ ,

\begin{matrix} | f (t, u) - f (t, v) | \leq | \frac{Γ (\frac{3}{2}) cos t}{{(t + 2 \sqrt{5})}^{2}} | | \frac{u - v}{(1 + u) (1 + v)} | \leq \frac{Γ (\frac{3}{2})}{20} | u - v |, \\ | I (u) - I (v) | \leq \frac{5}{(5 + u) (5 + v)} | u - v | \leq \frac{1}{5} | u - v |, \\ | J (u) - J (v) | \leq \frac{10}{(10 + u) (10 + v)} | u - v | \leq \frac{1}{10} | u - v | . \end{matrix}

Clearly, $L_{1} = \frac{Γ (\frac{3}{2})}{20}$ , $L_{2} = \frac{1}{10}$ , $L_{3} = \frac{1}{5}$ . Therefore,

ρ = σ_{1} L_{1} + \frac{m a^{2} L_{2}}{{(a - b)}^{2}} + \frac{m a L_{3}}{a - b} = \frac{10}{3 Γ (\frac{3}{2})} \frac{Γ (\frac{3}{2})}{20} + \frac{2}{5} + \frac{2}{5} = \frac{29}{30} < 1 .

Thus, all the assumptions of Theorem 3.1 are satisfied. Hence, BVPs (5.1) have aunique solution on $[0, 1]$ .

In addition, in this case, let $N_{1} = \frac{Γ (\frac{3}{2})}{20}$ , $N_{2} = N_{3} = 1$ . It is clear that $| f (t, u) | \leq N_{1}$ , $| J_{k} (u) | \leq N_{2}$ , $| I_{k} (u) | \leq N_{3}$ . Thus, BVPs (5.1) have at least one solution on $[0, 1]$ by Theorem 3.2.

Example 5.2 Consider the BVPs of impulsive nonlinear fractional orderdifferential equations:

{\begin{cases} {}^{c}D_{t}^{q} u (t)) = f (t, u (t), t \in J, t \neq \frac{1}{2}, \\ Δ u (\frac{1}{2}) = I (u (\frac{1}{2})), Δ u^{'} (\frac{1}{2}) = J (u (\frac{1}{2})), \\ a u (0) - b u (1) = 0, a u^{'} (0) - b u^{'} (1) = 0 . \end{cases}

(5.2)

Let $a = 2$ , $b = 1$ , $q = \frac{3}{2}$ , $f (t, u) = | \frac{u (t) ln u (t)}{5 (1 + t^{2})} |$ , $I (u) = J (u) = \frac{1}{16 (1 + u)}$ . It is easy to see that (H₄) holds. By a simplecomputation, we have

\begin{aligned} f_{0} = \underset{u \to 0}{lim inf} min_{t \in [0, 1]} | \frac{u ln u}{5 (1 + t^{2}) u} | = \underset{u \to 0}{lim inf} \frac{| ln u |}{10} = + \infty, \\ f_{\infty} = \underset{u \to \infty}{lim inf} min_{t \in [0, 1]} | \frac{u ln u}{5 (1 + t^{2}) u} | = \underset{u \to \infty}{lim inf} \frac{| ln u |}{10} = + \infty . \end{aligned}

Take $c = 1$ , it is clear that $3 \bar{N} < \frac{3}{4} < c$ . For $\frac{1}{4} \leq u \leq 1$ , $f (t, u) = \frac{- u ln u}{5 (1 + t^{2})}$ , we can obtain that $f (t, u)$ arrives at maximum at $u = \frac{1}{e} \in [\frac{1}{4}, 1]$ , $t = 0$ . Thus, we have

Φ (1) = max_{t \in [0, 1], u \in [\frac{1}{4}, 1]} f (t, u) = f (0, \frac{1}{e}) = \frac{1}{5 e} \approx 0.0736 < \frac{1}{3 σ_{1}} = \frac{\sqrt{π}}{20} \approx 0.0886 .

Thus it follows that BVPs (5.2) have at least two positive solutions $u_{1}$ , $u_{2}$ with $0 < ∥ u_{1} ∥ < 1 < ∥ u_{2} ∥$ by Theorem 4.1.

References

Lakshmikantham V, Leela S: Nagumo-type uniqueness result for fractional differential equations. Nonlinear Anal. 2009, 71: 2886-2889. 10.1016/j.na.2009.01.169
Article MathSciNet MATH Google Scholar
Chen F, Zhou Y: Attractivity of fractional functional differential equations. Comput. Math. Appl. 2011, 62: 1359-1369. 10.1016/j.camwa.2011.03.062
Article MathSciNet MATH Google Scholar
Chang Y, Nieto J: Some new existence results for fractional differential inclusions with boundaryconditions. Math. Comput. Model. 2009, 49: 605-609. 10.1016/j.mcm.2008.03.014
Article MathSciNet MATH Google Scholar
Kilbas AA, Trujillo JJ: Differential equations of fractional order: methods, results and problems-I. Appl. Anal. 2001, 78: 153-192. 10.1080/00036810108840931
Article MathSciNet MATH Google Scholar
Kilbas AA, Trujillo JJ: Differential equations of fractional order: methods, results and problems-II. Appl. Anal. 2002, 81: 435-493. 10.1080/0003681021000022032
Article MathSciNet MATH Google Scholar
Bai Z: On positive solutions of a nonlocal fractional boundary value problem. Nonlinear Anal. 2010, 72: 916-924. 10.1016/j.na.2009.07.033
Article MathSciNet MATH Google Scholar
Zhang X, Liu L, Wu Y: Multiple positive solutions of a singular fractional differential equation withnegatively perturbed term. Math. Comput. Model. 2012, 55(3):1263-1274.
Article MathSciNet MATH Google Scholar
Zhao Y, Sun S, Han Z, et al.: The existence of multiple positive solutions for boundary value problems ofnonlinear fractional differential equations. Commun. Nonlinear Sci. Numer. Simul. 2011, 16(4):2086-2097. 10.1016/j.cnsns.2010.08.017
Article MathSciNet MATH Google Scholar
Bai Z, Qiu T: Existence of positive solution for singular fractional differential equation. Appl. Math. Comput. 2009, 215(7):2761-2767. 10.1016/j.amc.2009.09.017
Article MathSciNet MATH Google Scholar
Zhao Y, Sun S, Han Z, et al.: Positive solutions for boundary value problems of nonlinear fractionaldifferential equations. Appl. Math. Comput. 2011, 217(16):6950-6958. 10.1016/j.amc.2011.01.103
Article MathSciNet MATH Google Scholar
Goodrich C: Existence of a positive solution to a class of fractional differentialequations. Appl. Math. Lett. 2010, 23: 1050-1055. 10.1016/j.aml.2010.04.035
Article MathSciNet MATH Google Scholar
Salem H: On the existence of continuous solutions for a singular system of nonlinearfractional differential equations. Appl. Math. Comput. 2008, 198: 445-452. 10.1016/j.amc.2007.08.063
Article MathSciNet MATH Google Scholar
Bai Z, Lv H: Positive solutions for boundary value problem of nonlinear fractional differentialequation. J. Math. Anal. Appl. 2005, 311: 495-505. 10.1016/j.jmaa.2005.02.052
Article MathSciNet Google Scholar
Zhao Y, Chen H, Zhang Q: Existence and multiplicity of positive solutions for nonhomogeneous boundary valueproblems with fractional q -derivatives. Bound. Value Probl. 2013., 2013: Article ID 103
Google Scholar
Li X, Chen F, Li X: Generalized anti-periodic boundary value problems of impulsive fractionaldifferential equations. Commun. Nonlinear Sci. Numer. Simul. 2013, 18: 28-41. 10.1016/j.cnsns.2012.06.014
Article MathSciNet Google Scholar
Tian Y, Bai Z: Impulsive boundary value problem for differential equations with fractionalorder. Differ. Equ. Dyn. Syst. 2013, 21(3):253-260. 10.1007/s12591-012-0150-6
Article MathSciNet MATH Google Scholar
Zhao KH, Gong P: Existence of positive solutions for a class of higher-order Caputo fractionaldifferential equation. Qual. Theory Dyn. Syst. 2014. 10.1007/s12346-014-0121-0
Google Scholar
Bainov DD, Simeonov PS: Impulsive Differential Equations: Periodic Solutions and Applications. Longman, New York; 1993.
MATH Google Scholar
Lakshmikantham V, Bainov DD, Simeonov PS: Theory of Impulsive Differential Equations. World Scientific, Singapore; 1989.
Book MATH Google Scholar
Benchohra M, Henderson J, Ntouyas SK 2. In Impulsive Differential Equations and Inclusions. Hindawi Publishing Corporation, New York; 2006.
Chapter Google Scholar
Kilbas A, Srivastava H, Trujillo J North-Holland Mathematics Studies 204. In Theory and Applications of Fractional Differential Equations. Elsevier, Amsterdam; 2006.
Google Scholar
Podlubny I: Fractional Differential Equations. Academic Press, New York; 1993.
MATH Google Scholar
Sun JX: Nonlinear Functional Analysis and Its Application. Science Press, Beijing; 2008. (in Chinese)
Google Scholar
Hale JK: Theory of Functional Differential Equations. Springer, New York; 1977.
Book MATH Google Scholar
Guo D, Lakshmikantham V, Liu X Mathematics and Its Applications 373. In Nonlinear Integral Equations in Abstract Spaces. Kluwer Academic, Dordrecht; 1996.
Chapter Google Scholar

Download references

Acknowledgements

The authors thank the referees for their valuable comments and suggestions for theimprovement of the manuscript. This work is supported by the National NaturalSciences Foundation of Peoples Republic of China under Grant No. 11161025 and YunnanProvince Natural Scientific Research Fund Project under Grant No. 2011FZ058.

Author information

Authors and Affiliations

Department of Applied Mathematics, Kunming University of Science and Technology, Kunming, Yunnan, 650093, China
Kaihong Zhao & Ping Gong

Authors

Kaihong Zhao
View author publications
You can also search for this author in PubMed Google Scholar
Ping Gong
View author publications
You can also search for this author in PubMed Google Scholar

Corresponding author

Correspondence to Kaihong Zhao.

Additional information

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

All authors contributed equally and significantly in writing this paper. All authorsread and approved the final manuscript.

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (https://creativecommons.org/licenses/by/4.0), which permits use, duplication, adaptation, distribution, and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.

Reprints and permissions

About this article

Cite this article

Zhao, K., Gong, P. Positive solutions for impulsive fractional differential equations with generalizedperiodic boundary value conditions. Adv Differ Equ 2014, 255 (2014). https://doi.org/10.1186/1687-1847-2014-255

Download citation

Received: 20 June 2014
Accepted: 09 September 2014
Published: 29 September 2014
DOI: https://doi.org/10.1186/1687-1847-2014-255

Positive solutions for impulsive fractional differential equations with generalizedperiodic boundary value conditions

Abstract

1 Introduction

2 Preliminaries

3 Existence of single positive solutions

4 Existence of multiple positive solutions

5 Illustrative examples

References

Acknowledgements

Author information

Authors and Affiliations

Corresponding author

Additional information

Competing interests

Authors’ contributions

Rights and permissions

About this article

Cite this article

Share this article

Keywords