Traveling Waves in a Nonlocal Dispersal SIR Model with Standard Incidence Rate and Nonlocal Delayed Transmission

Wu, Kuilin; Zhou, Kai

doi:10.3390/math7070641

Open AccessArticle

Traveling Waves in a Nonlocal Dispersal SIR Model with Standard Incidence Rate and Nonlocal Delayed Transmission

by

Kuilin Wu

¹ and

Kai Zhou

^2,*

¹

Department of Mathematics, Guizhou University, Guiyang 550025, China

²

School of Mathematics and Computer, Chizhou University, Chizhou 247000, China

^*

Author to whom correspondence should be addressed.

Mathematics 2019, 7(7), 641; https://doi.org/10.3390/math7070641

Submission received: 15 April 2019 / Revised: 6 July 2019 / Accepted: 17 July 2019 / Published: 18 July 2019

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Abstract

:

In this paper, we study the traveling wave solutions for a nonlocal dispersal SIR epidemic model with standard incidence rate and nonlocal delayed transmission. The existence and nonexistence of traveling wave solutions are determined by the basic reproduction number of the corresponding reaction system and the minimal wave speed. To prove these results, we apply the Schauder’s fixed point theorem and two-sided Laplace transform. The main difficulties are that the complexity of the incidence rate in the epidemic model and the lack of regularity for nonlocal dispersal operator.

Keywords:

SIR model; nonlocal dispersal; traveling wave solutions; nonlocal delayed transmission; Schauder’s fixed point theorem

1. Introduction

Due to the important significance in modeling the disease transmission, traveling wave solution has been intensively researched in many epidemic models, such as the SIR epidemic models and their various extensions. For instance, Hosono and Ilyas [1] considered the following epidemic model:

\{\begin{matrix} \frac{\partial S (x, t)}{\partial t} = d_{1} \frac{\partial^{2} S (x, t)}{\partial x^{2}} - β S (x, t) I (x, t), \\ \frac{\partial I (x, t)}{\partial t} = d_{2} \frac{\partial^{2} I (x, t)}{\partial x^{2}} + β S (x, t) I (x, t) - γ I (x, t), \\ \frac{\partial R (x, t)}{\partial t} = d_{3} \frac{\partial^{2} R (x, t)}{\partial x^{2}} + γ I (x, t), \end{matrix}

(1)

where

S, I

and R denote the densities of the susceptible, infected and removed individuals, respectively.

d_{i} > 0, i = 1, 2, 3

are the diffusion rates, and the positive constants

β, γ

denote the transmission rate and the recovery rate, respectively. They have proved that system (1) admits a pair of traveling wave solution

(S (x + c t), I (x + c t))

satisfying

S (- \infty) = S_{- \infty} > S (\infty) = S_{\infty}, I (\pm \infty) = 0

if

\frac{β S_{- \infty}}{γ} > 1

and the wave speed

c \geq c^{*} = 2 \sqrt{β S_{- \infty} d_{2} (1 - \frac{γ}{β S_{- \infty}})}

. Wang and Wu [2] considered the existence and nonexistence of traveling wave solution for a diffusive Kermack–McKendrick epidemic model with nonlocal delayed transmission. The incidence rate in these two papers is bilinear form

β S I

. Since then, there has been extensive research with traveling wave solutions for delayed diffusive SIR models with various incidence rates, such as

\frac{β S I}{1 + α I}, β I^{p} S^{q} (p, q > 0)

and general form

f (S) g (I)

, see [3,4,5,6,7,8,9,10,11,12,13,14]. There have also been some papers about traveling wave solutions for delayed diffusive SIR models with external supplies [15,16] and delayed diffusive SIRS epidemic models [17,18].

On the other hand, the traveling wave solution for diffusive SIR models with a standard incidence rate has attracted more and more attention. Wang et al. [19] have considered the following SIR disease outbreak model with the standard incidence rate

\{\begin{matrix} \frac{\partial S (x, t)}{\partial t} = d_{1} \frac{\partial^{2} S (x, t)}{\partial x^{2}} - \frac{β S (x, t) I (x, t)}{S (x, t) + I (x, t)}, \\ \frac{\partial I (x, t)}{\partial t} = d_{2} \frac{\partial^{2} I (x, t)}{\partial x^{2}} + \frac{β S (x, t) I (x, t)}{S (x, t) + I (x, t)} - γ I (x, t), \\ \frac{\partial R (x, t)}{\partial t} = d_{3} \frac{\partial^{2} R (x, t)}{\partial x^{2}} + γ I (x, t) . \end{matrix}

(2)

They have obtained full information about the existence and nonexistence of traveling wave solutions. Li et al. [20] also have studied diffusive SIR epidemic model with standard incidence rate, which is different from system (2) that they considered the effect of nonlocal delayed transmission. Wang and Wang [21] have studied the following diffusive SIR epidemic model

\{\begin{matrix} \frac{\partial S (x, t)}{\partial t} = d_{1} \frac{\partial^{2} S (x, t)}{\partial x^{2}} - \frac{β S (x, t) I (x, t)}{S (x, t) + I (x, t) + R (x, t)}, \\ \frac{\partial I (x, t)}{\partial t} = d_{2} \frac{\partial^{2} I (x, t)}{\partial x^{2}} + \frac{β S (x, t) I (x, t)}{S (x, t) + I (x, t) + R (x, t)} - (γ + δ) I (x, t), \\ \frac{\partial R (x, t)}{\partial t} = d_{3} \frac{\partial^{2} R (x, t)}{\partial x^{2}} + γ I (x, t), \end{matrix}

(3)

where

δ > 0

denotes the death rate due to the disease. They have obtained that system (3) has a traveling wave solution

(S (x + c t), I (x + c t), R (x + c t))

satisfying

S (- \infty) = S_{- \infty} > S (\infty) = S_{\infty}

,

I (\pm \infty) = 0, R (- \infty) = 0

,

R (\infty) = \frac{γ (S_{- \infty} - S_{\infty})}{γ + δ}

if

\frac{β}{γ + δ} > 1, c > c^{*} = 2 \sqrt{d_{2} (β - γ - δ)}

and

d_{3} < 2 d_{2}

. More recently, Zhen, Wei, Tian et al. [22] have considered the following diffusive SIR epidemic model with standard incidence rate and spatiotemporal delay

\{\begin{matrix} \frac{\partial S (x, t)}{\partial t} = d_{1} \frac{\partial^{2} S (x, t)}{\partial x^{2}} - \frac{β S (x, t) (G * I) (x, t)}{S (x, t) + (G * I) (x, t) + R (x, t)}, \\ \frac{\partial I (x, t)}{\partial t} = d_{2} \frac{\partial^{2} I (x, t)}{\partial x^{2}} + \frac{β S (x, t) (G * I) (x, t)}{S (x, t) + (G * I) (x, t) + R (x, t)} - (γ + δ) I (x, t), \\ \frac{\partial R (x, t)}{\partial t} = d_{3} \frac{\partial^{2} R (x, t)}{\partial x^{2}} + γ I (x, t), \end{matrix}

(4)

where

(G * I) (x, t) = \int_{- \infty}^{t} \int_{- \infty}^{\infty} G (x - y, t - s) I (y, s) d y d s .

The spatiotemporal kernel

G (x - y, t - s)

describes the interaction between the infective and the susceptible individuals at location x and the present time t, which occurred at location y and at earlier time s. It should be emphasized that the incidence rate in system (3)–(4) is different from the previous one in model (2), which is

\frac{β S I}{S + I}

. The incidence rate

\frac{β S I}{S + I + R}

makes the diffusive systems be totally coupled, and the corresponding traveling wave systems consist of three equations, where few papers have dealt with it, see [23].

The diffusion terms of the above systems are Laplacian operators that account for random motion. However, due to the more frequent interaction with other people, the movements of individuals may be not limited to a small area. Thus, recently, various integral operators have been widely used to model the diffusion phenomena, for example, in [24,25,26]. Yang et al. [27] considered the following nonlocal dispersal epidemic model

\{\begin{matrix} \frac{\partial}{\partial t} S (x, t) = d_{1} [J * S (x, t) - S (x, t)] - β S (x, t) I (x, t), \\ \frac{\partial}{\partial t} I (x, t) = d_{2} [J * I (x, t) - I (x, t)] + β S (x, t) I (x, t) - γ I (x, t), \\ \frac{\partial}{\partial t} R (x, t) = d_{3} [J * R (x, t) - R (x, t)] + γ I (x, t), \end{matrix}

where

J (\cdot)

denotes the probability distribution of rates of dispersal and

J * u - u

can describe the net rate of increase due to the dispersal of subpopulation u, where

J * u (x, t)

is the standard convolution with space invariable x and u can be either

S, I

or R. Under some assumptions about the dispersal kernel function

J (\cdot)

, they obtained the existence and nonexistence of traveling wave solutions. Since then, many researchers pay more attention to the study of traveling wave solutions of nonlocal dispersal SIR epidemic models, for instance, in [28,29,30,31,32,33]. Therefore, in this paper, we will consider the corresponding nonlocal dispersal model of system (4) that is the following nonlocal dispersal SIR epidemic model with nonlocal delayed transmission:

\{\begin{matrix} \frac{\partial S (x, t)}{\partial t} = d_{1} (J * S (x, t) - S (x, t)) - \frac{β S (x, t) (G * I) (x, t)}{S (x, t) + (G * I) (x, t) + R (x, t)}, \\ \frac{\partial I (x, t)}{\partial t} = d_{2} (J * I (x, t) - I (x, t)) + \frac{β S (x, t) (G * I) (x, t)}{S (x, t) + (G * I) (x, t) + R (x, t)} - (γ + δ) I (x, t), \\ \frac{\partial R (x, t)}{\partial t} = d_{3} (J * R (x, t) - R (x, t)) + γ I (x, t) . \end{matrix}

(5)

Throughout this paper, we give the following assumptions on the kernel functions J and G:

(J)

J \in C^{1} (R), J (y) = J (- y) \geq 0, \int_{- \infty}^{\infty} J (y) d y = 1, J

is compactly supported. Furthermore, for any

v \in [0, \tilde{v})

,

\int_{- \infty}^{\infty} J (y) e^{- v y} d y < + \infty,

and

\int_{- \infty}^{\infty} J (y) e^{- v y} d y \to + \infty

as

v \to {\tilde{v}}^{-}

where

\tilde{v}

may be

+ \infty

;

(G)

G (y, s) = G (- y, s) \geq 0, \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) d y d s = 1, \int_{0}^{\infty} \int_{- \infty}^{\infty} s G (y, s) d y d s < \infty

and

G (y, s)

is Lipschitz continuous with the space variable y. Moreover, for each

c \geq 0

,

\int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) e^{- λ (y + c s)} d y d s < \infty, λ \in [0, \infty),

\int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) e^{- λ (y + c s)} d y d s \to \infty, a s λ \to \infty .

The remainder of this paper is organized as follows. In Section 2, we introduce some preliminaries. In Section 3, we prove the existence of traveling waves by the Schauder’s fixed point theorem and the method of upper-lower solution. We will discuss the nonexistence of the traveling waves in Section 4. Finally, we will provide the conclusions and give a discussion about the effect of the nonlocal delayed transmission on the propagation of the disease in Section 5.

2. Some Preliminaries

In this section, we will consider the traveling wave solutions for system (5). Upon substituting

S (I, R) (x, t) = S (I, R) (x + c t)

into (5), and denoting

ξ = x + c t

, we derive the following wave profile system for system (5):

\{\begin{matrix} c S^{'} (ξ) = d_{1} (J * S (ξ) - S (ξ)) - \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)}, \\ c I^{'} (ξ) = d_{2} (J * I (ξ) - I (ξ)) + \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} - (γ + δ) I (ξ), \\ c R^{'} (ξ) = d_{3} (J * R (ξ) - R (ξ)) + γ I (ξ), \end{matrix}

(6)

where

(G * I) (ξ) = \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) I (ξ - y - c s) d y d s .

We assume that system (6) has a disease free equilibrium

(S_{0}, 0, 0)

, where

S_{0} > 0

is a constant. According to the meaning of mathematical epidemiology, we intend to find solution

(S (ξ), I (ξ), R (ξ))

for system (6) which is nonnegative and satisfies the following asymptotic boundary conditions:

S (- \infty) = S_{0}, lim_{ξ \to + \infty} S (ξ) : = S_{\infty} < S_{0}, I (\pm \infty) = 0, R (- \infty) = 0 .

Moreover, if R is bounded, then

lim_{ξ \to + \infty} R (ξ)

exists and

R (\infty) = \frac{γ (S_{0} - S_{\infty})}{γ + δ} .

For any

λ, c > 0

, by linearizing the second equation of system (6) at

(S_{0}, 0, 0)

and letting

I (ξ) = e^{λ ξ}

, we obtain the characteristic equation

\begin{matrix} Δ (λ, c) & = d_{2} (\int_{- \infty}^{\infty} J (y) e^{- λ y} d y - 1) - c λ + β \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) e^{- λ (y + c s)} d y d s - γ - δ . \end{matrix}

For the convenience, we denote

\bar{G} (λ, c) = \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) e^{- λ (y + c s)} d y d s,

then

Δ (λ, c) = d_{2} (\int_{- \infty}^{\infty} J (y) e^{- λ y} d y - 1) - c λ + β \bar{G} (λ, c) - γ - δ .

By a direct calculation, and using (J) and (G), we have

\begin{matrix} Δ (0, c) = β - γ - δ, Δ (λ, + \infty) = - \infty, \\ \frac{\partial Δ (0, c)}{\partial λ} = - c (1 + β \int_{0}^{\infty} \int_{- \infty}^{\infty} s G (y, s) d y d s) < 0, \\ \frac{\partial Δ (λ, c)}{\partial c} = - λ - λ β \int_{0}^{\infty} \int_{- \infty}^{\infty} s G (y, s) e^{- λ (y + c s)} d y d s < 0, \\ \frac{\partial^{2} Δ (λ, c)}{\partial λ^{2}} = d_{2} \int_{- \infty}^{\infty} y^{2} J (y) e^{- λ y} d y + β \int_{0}^{\infty} \int_{- \infty}^{\infty} {(y - c s)}^{2} G (y, s) e^{- λ (y + c s)} d y d s > 0 . \end{matrix}

Therefore, we have the following lemma.

Lemma 1.

Assume that

R_{0} = \frac{β}{γ + δ} > 1

, then there exist

c^{*} > 0, λ^{*} > 0

such that

Δ (λ^{*}, c^{*}) = 0, \frac{\partial Δ}{\partial λ} (λ, c) |_{(λ^{*}, c^{*})} = 0 .

Furthermore,

(i): if $0 < c < c^{*}$ , then $Δ (λ, c) > 0$ for all $λ > 0$ ;
(ii): if $c > c^{*}$ , then $Δ (λ, c) = 0$ has two different positive roots $λ_{1} (c), λ_{2} (c)$ with $0 < λ_{1} (c) < λ^{*} < λ_{2} (c)$ and

$Δ (λ, c) {\begin{matrix} > 0 λ \in [0, λ_{1} (c)) \cup (λ_{2} (c), \infty), \\ < 0 λ \in (λ_{1} (c), λ_{2} (c)) . \end{matrix}$

When

c > c^{*}, i = 1, 2

, we denote

λ_{i} (c)

as

λ_{i}

.

For any

c > 0

, we also define function

Δ_{1} (λ, c)

as follows:

Δ_{1} (λ, c) = c λ - d_{3} (\int_{- \infty}^{\infty} J (x) e^{- λ x} d x - 1) .

Then,

\frac{\partial Δ_{1} (0, c)}{\partial λ} = c > 0, \frac{\partial^{2} Δ_{1} (λ, c)}{\partial λ^{2}} < 0 .

Thus, there exists

λ_{0} > 0

such that

Δ_{1} (λ, c) > 0

for any

λ \in (0, λ_{0})

.

3. Existence of Traveling Waves

3.1. Upper-Lower Solution of System (6)

In this section, we will prove the existence of traveling wave solutions for system (5). In the remainder of this section, we fix

R_{0} = \frac{β}{γ + δ} > 1, c > c^{*}

. At first, we define six nonnegative continuous functions as follows:

\begin{matrix} S_{+} (ξ) & = S_{0}, & S_{-} (ξ) & = \{\begin{matrix} S_{0} (1 - σ e^{α ξ}), & ξ < ξ_{1}, \\ 0, & ξ \geq ξ_{1}, \end{matrix} \\ I_{+} (ξ) & = \{\begin{matrix} e^{λ_{1} ξ}, & ξ < ξ_{2}, \\ \frac{(β - γ - δ) S_{0}}{γ + δ}, & ξ \geq ξ_{2}, \end{matrix} & I_{-} (ξ) & = \{\begin{matrix} e^{λ_{1} ξ} (1 - M e^{η ξ}), & ξ < ξ_{3}, \\ 0, & ξ \geq ξ_{3}, \end{matrix} \\ R_{+} (ξ) & = M_{1} e^{η ξ}, R_{-} (ξ) = 0, \end{matrix}

where

σ, α, M, M_{1}

are all positive constants,

σ = \frac{1}{α}, η \in (0, λ_{0})

is sufficiently small satisfying

η < min {α, λ_{1}, λ_{2} - λ_{1}}

.

Now, we have the following lemmas.

Lemma 2.

For sufficiently large

M_{1}

, the following inequalities hold:

\begin{matrix} c S_{+}^{'} (ξ) & \geq d_{1} (J * S_{+} (ξ) - S_{+} (ξ)) - \frac{β S_{+} (ξ) (G * I_{-}) (ξ)}{S_{+} (ξ) + (G * I_{-}) (ξ) + R_{+} (ξ)}, \end{matrix}

(7)

\begin{matrix} c I_{+}^{'} (ξ) & \geq d_{2} (J * I_{+} (ξ) - I_{+} (ξ)) + \frac{β S_{+} (ξ) (G * I_{+}) (ξ)}{S_{+} (ξ) + (G * I_{+}) (ξ) + R_{-} (ξ)} \\ - (γ + δ) I_{+} (ξ), ξ \neq ξ_{2}, \end{matrix}

(8)

\begin{matrix} c R_{+}^{'} (ξ) & \geq d_{3} (J * R_{+} (ξ) - R_{+} (ξ)) + γ I_{+} (ξ) . \end{matrix}

(9)

Proof.

Since

G * I_{-} (ξ) \geq 0

and

S_{+} (ξ) = S_{0}

is a positive constant, then inequality (7) holds naturally.

Next, we consider inequality (8). Due to (J), (G) and the definition of

I_{+} (ξ)

, we have

\begin{matrix} J * I_{+} (ξ) & \leq min \{e^{λ_{1} ξ} \int_{- \infty}^{\infty} J (y) e^{- λ_{1} y} d y, \frac{(β - γ - δ) S_{0}}{γ + δ}\}, \\ G * I_{+} (ξ) & \leq min \{e^{λ_{1} ξ} \bar{G} (λ_{1}, c), \frac{(β - γ - δ) S_{0}}{γ + δ}\} . \end{matrix}

(10)

If

ξ < ξ_{2}

, by Lemma 1, (10) and

\frac{S_{+} (ξ) (G * I_{+}) (ξ)}{S_{+} (ξ) + (G * I_{+}) (ξ) + R_{-} (ξ)} \leq G * I_{+} (ξ)

, we conclude that

I_{+} (ξ) = e^{λ_{1} ξ}

satisfies

\begin{matrix} c I_{+}^{'} (ξ) & = d_{2} (\int_{- \infty}^{\infty} J (y) e^{- λ_{1} y} d y - 1) I_{+} (ξ) + β I_{+} (ξ) \bar{G} (λ_{1}, c) - (γ + δ) I_{+} (ξ) \\ \geq d_{2} (J * I_{+} (ξ) - I_{+} (ξ)) + β (G * I_{+}) (ξ) - (γ + δ) I_{+} (ξ) \\ \geq d_{2} (J * I_{+} (ξ) - I_{+} (ξ)) + \frac{β S_{+} (ξ) (G * I_{+}) (ξ)}{S_{+} (ξ) + (G * I_{+}) (ξ) + R_{-} (ξ)} - (γ + δ) I_{+} (ξ) . \end{matrix}

If

ξ > ξ_{2}

, then

S_{+} (ξ) = S_{0}, I_{+} (ξ) = \frac{(β - γ - δ) S_{0}}{γ + δ}

and

R_{-} (ξ) = 0

. Since

\frac{β x y}{x + y}

is nondecreasing with respect with

x, y

, we have that

\begin{matrix} \frac{β S_{+} (ξ) (G * I_{+}) (ξ)}{S_{+} (ξ) + (G * I_{+}) (ξ) + R_{-} (ξ)} - (γ + δ) I_{+} (ξ) \\ \leq \frac{β S_{0} I_{+} (ξ)}{S_{0} + I_{+} (ξ)} - (γ + δ) I_{+} (ξ) \\ = [\frac{β S_{0} (γ + δ)}{(γ + δ) S_{0} + (β - γ - δ) S_{0}} - (γ + δ)] I_{+} (ξ) = 0 . \end{matrix}

Thus, formula (8) is true.

Finally, we consider inequality (9). When

ξ < ξ_{2}

, then

I_{+} (ξ) = e^{λ_{1} ξ}

and

R_{+} (ξ) = M_{1} e^{η ξ}

. It suffices to prove

c η M_{1} e^{η ξ} \geq d_{3} M_{1} e^{η ξ} (\int_{- \infty}^{\infty} J (x) e^{- η x} d x - 1) + γ e^{λ_{1} ξ},

that is

M_{1} e^{η ξ} [c η - d_{3} (\int_{- \infty}^{\infty} J (x) e^{- η x} d x - 1)] \geq γ e^{λ_{1} ξ} .

(11)

Due to

η \in (0, λ_{0})

, we have

Δ_{1} (η, c) > 0

, and inequality (11) is equivalent to

M_{1} \geq \frac{γ e^{(λ_{1} - η) ξ}}{Δ_{1} (η, c)} .

Furthermore, since

η < λ_{1}

and

ξ < ξ_{2}

, then formula (9) holds if we take

M_{1} > \frac{γ e^{(λ_{1} - η) ξ_{2}}}{Δ_{1} (η, c)} .

Similarly, for

ξ > ξ_{2}

, formula (9) is true if we take

M_{1} > \frac{γ (β - γ - δ) S_{0} e^{- η ξ_{2}}}{(γ + δ) Δ_{1} (η, c)} .

Therefore, we take

M_{1} > max \{\frac{γ e^{(λ_{1} - η) ξ_{2}}}{Δ_{1} (η, c)}, \frac{γ (β - γ - δ) S_{0} e^{- η ξ_{2}}}{(γ + δ) Δ_{1} (η, c)}\},

then inequality (9) is true. The proof is complete.

Lemma 3.

Suppose that

α < λ_{1}

and σ are large enough. Then, the function

S_{-} (ξ)

satisfies

c S_{-}^{'} (ξ) \leq d_{1} (J * S_{-} (ξ) - S_{-} (ξ)) - \frac{β S_{-} (ξ) (G * I_{+}) (ξ)}{S_{-} (ξ) + (G * I_{+}) (ξ) + R_{-} (ξ)}

(12)

for any

ξ \neq ξ_{1} : = \frac{1}{α} ln \frac{1}{σ} .

Proof.

According to the definition of

S_{-} (ξ)

and (J), we can obtain that

J * S_{-} (ξ) \geq max \{S_{0} - S_{0} σ e^{α ξ} \int_{- \infty}^{\infty} J (y) e^{- α y} d y, 0\} .

(13)

If

ξ > ξ_{1}

,

S_{-} (ξ) = 0

, then inequality (12) holds.

By taking

σ

large enough such that

σ > e^{- α ξ_{2}}

, then

\frac{1}{α} ln \frac{1}{σ} = ξ_{1} < ξ_{2}

. Therefore, if

ξ < ξ_{1}

,

S_{-} (ξ) = S_{0} (1 - σ e^{α ξ})

,

I_{+} (ξ) = e^{λ_{1} ξ}

. Due to

\frac{S_{-} (ξ) (G * I_{+}) (ξ)}{S_{-} (ξ) + (G * I_{+}) (ξ) + R_{-} (ξ)} \leq G * I_{+} (ξ)

, (10) and (13), in order to prove inequality (12), we only need to prove

\begin{matrix} c S_{-}^{'} (ξ) & \leq d_{1} [S_{0} - S_{0} σ e^{α ξ} \int_{- \infty}^{\infty} J (y) e^{- α y} d y - S_{-} (ξ)] - β e^{λ_{1} ξ} \bar{G} (λ_{1}, c) . \end{matrix}

(14)

Through a simple calculation, we know that formula (14) is equivalent to

- S_{0} σ [c α - d_{1} (\int_{- \infty}^{\infty} J (y) e^{- α y} d y - 1)] + β e^{(λ_{1} - α) ξ} \bar{G} (λ_{1}, c) \leq 0 .

Since

α < λ_{1}

and

ξ < ξ_{1}

, it suffices to show that

- S_{0} σ [c α - d_{1} (\int_{- \infty}^{\infty} J (y) e^{- α y} d y - 1)] + β e^{(λ_{1} - α) ξ_{1}} \bar{G} (λ_{1}, c) \leq 0,

that is

- S_{0} σ [c α - d_{1} (\int_{- \infty}^{\infty} J (y) e^{- α y} d y - 1)] + β σ^{\frac{α - λ_{1}}{α}} \bar{G} (λ_{1}, c) \leq 0 .

By taking sufficiently large

σ

, the above is true, and the proof is complete. □

Lemma 4.

Supposing that M is large enough, the function

I_{-} (ξ)

satisfies the inequality

c I_{-}^{'} (ξ) \leq d_{2} (J * I_{-} (ξ) - I_{-} (ξ)) + \frac{β S_{-} (ξ) (G * I_{-}) (ξ)}{S_{-} (ξ) + (G * I_{-}) (ξ) + R_{+} (ξ)} - (γ + δ) I_{-} (ξ)

(15)

for

ξ \neq ξ_{3}

.

Proof.

First, by the definition of

I_{-} (ξ)

and (J), (G), we have

\begin{matrix} J * I_{-} (ξ) & \geq max \{e^{λ_{1} ξ} \int_{- \infty}^{\infty} J (y) e^{- λ_{1} y} d y - M e^{(λ_{1} + η) ξ} \int_{- \infty}^{\infty} J (y) e^{- (λ_{1} + η) y} d y, 0\}, \\ G * I_{-} (ξ) & \geq max \{e^{λ_{1} ξ} \bar{G} (λ_{1}, c) - M e^{(λ_{1} + η) ξ} \bar{G} (λ_{1} + η, c), 0\} . \end{matrix}

If

ξ > ξ_{3}

, then

I_{-} (ξ) = 0

. Thus, inequality (15) is obviously true.

If

ξ < ξ_{3}

, we choose an M large enough such that

ξ_{3} = \frac{1}{η} ln \frac{1}{M} < \frac{1}{α} ln \frac{1}{σ} = ξ_{1}

, then

S_{-} (ξ) = S_{0} (1 - σ e^{α ξ}) \leq S_{0}

,

I_{-} (ξ) = e^{λ_{1} ξ} (1 - M e^{η ξ})

. In order to prove inequality (15), it is only necessary to prove

\begin{matrix} c I_{-}^{'} (ξ) & \leq d_{2} (J * I_{-} (ξ) - I_{-} (ξ)) + β G * I_{-} (ξ) - (γ + δ) I_{-} (ξ) \\ - \frac{β [S_{0} - S_{-} (ξ) + (G * I_{-}) (ξ) + R_{+} (ξ)]}{S_{0} + (G * I_{-}) (ξ) + R_{+} (ξ)} G * I_{-} (ξ) . \end{matrix}

By the estimate of

G * I_{-} (ξ)

and the definition of

Δ (λ, c)

, it suffices to prove that

β [S_{0} - S_{-} (ξ) + (G * I_{-}) (ξ) + R_{+} (ξ)] (G * I_{-}) (ξ) \leq - M Δ (λ_{1} + η, c) e^{(λ_{1} + η) ξ} \cdot S_{0} .

(16)

Since

G * I_{-} (ξ) \leq e^{λ_{1} ξ} \bar{G} (λ_{1}, c)

, formula (16) is true if

\begin{matrix} β (S_{0} σ e^{α ξ} + e^{λ_{1} ξ} \bar{G} (λ_{1}, c) + M_{1} e^{η ξ}) e^{λ_{1} ξ} \bar{G} (λ_{1}, c) \leq - S_{0} M Δ (λ_{1} + η, c) e^{(λ_{1} + η) ξ} . \end{matrix}

(17)

Due to

ξ < ξ_{1}, η < α, η < λ_{1}, Δ (λ_{1} + η, c) < 0

, by taking M be a constant number which satisfies

M \geq \frac{β \bar{G} (λ_{1}, c) [S_{0} σ^{\frac{η}{α}} + σ^{\frac{η - λ_{1}}{α}} \bar{G} (λ_{1}, c) + M_{1}]}{- S_{0} Δ (λ_{1} + η, c)},

formula (17) holds.

In summary, there exists sufficiently large M, such that

I_{-} (ξ)

satisfies inequality (15). The proof is complete. □

By Lemmas 2–4, we know that the continuous function

(S_{+} (ξ), I_{+} (ξ),

R_{+} (ξ))

and

(S_{-} (ξ), I_{-} (ξ), R_{-} (ξ))

is a pair of upper-lower solutions for system (6).

From now on, we will establish the existence of traveling wave solutions of (4). Due to the lack of regularity of nonlocal dispersal operator, we first consider the traveling wave system (6) on a bounded interval. For this purpose, we take

X > \frac{1}{η} ln M

, and define the following set:

Γ_{X} = \{(ϕ (\cdot), χ (\cdot), ψ (\cdot)) \in C ([- X, X], R^{3}) |\begin{matrix} ϕ (- X) = S_{-} (- X), χ (- X) = I_{-} (- X), \\ ψ (- X) = R_{-} (- X), \\ S_{-} (ξ) \leq ϕ (ξ) \leq S_{0}, \\ I_{-} (ξ) \leq χ (ξ) \leq I_{+} (ξ), \\ R_{-} (ξ) \leq ψ (ξ) \leq R_{+} (ξ), \forall ξ \in [- X, X] \end{matrix}\} .

It is easy to know that

Γ_{X}

is a closed, convex subset of

C ([- X, X], R^{3})

. For any

(ϕ (\cdot), χ (\cdot), ψ (\cdot)) \in Γ_{X}

, we define

\begin{matrix} \tilde{ϕ} (ξ) = \{\begin{matrix} ϕ (X), & ξ > X, \\ ϕ (ξ), & | ξ | \leq X, \\ S_{-} (ξ), & ξ < - X, \end{matrix} \tilde{χ} (ξ) = \{\begin{matrix} χ (X), & ξ > X, \\ χ (ξ), & | ξ | \leq X, \\ I_{-} (ξ), & ξ < - X, \end{matrix} \end{matrix}

and

\begin{matrix} \tilde{ψ} (ξ) = \{\begin{matrix} ψ (X), & ξ > X, \\ ψ (ξ), & | ξ | \leq X, \\ R_{-} (ξ), & ξ < - X . \end{matrix} \end{matrix}

We consider the following initial value problem:

\begin{matrix} c S^{'} (ξ) & = d_{1} \int_{- \infty}^{\infty} J (y) \tilde{ϕ} (ξ - y) d y - d_{1} S (ξ) - \frac{β ϕ (ξ) (G * \tilde{χ}) (ξ)}{ϕ (ξ) + (G * \tilde{χ}) (ξ) + ψ (ξ)}, \end{matrix}

(18)

\begin{matrix} c I^{'} (ξ) & = d_{2} \int_{- \infty}^{\infty} J (y) \tilde{χ} (ξ - y) d y - (d_{2} + γ + δ) I (ξ) + \frac{β ϕ (ξ) (G * \tilde{χ}) (ξ)}{ϕ (ξ) + (G * \tilde{χ}) (ξ) + ψ (ξ)}, \end{matrix}

(19)

\begin{matrix} c R^{'} (ξ) & = d_{3} \int_{- \infty}^{\infty} J (y) \tilde{ψ} (ξ - y) d y - d_{3} R (ξ) + γ χ (ξ), \end{matrix}

(20)

with

S (- X) = S_{-} (- X), I (- X) = I_{-} (- X), R (- X) = R_{-} (- X) .

(21)

By the theory for ODE [34], problems (18)–(21) admit a unique solution

(S_{X} (ξ), I_{X} (ξ), R_{X} (ξ))

satisfying

S_{X} (\cdot), I_{X} (\cdot), R_{X} (\cdot) \in C^{1} ([- X, X])

. Furthermore, we define an operator

F = (F_{1}, F_{2}, F_{3})

:

Γ_{X} \to C ([- X, X])

such that, for any

ξ \in [- X, X],

F_{1} (ϕ, χ, ψ) (ξ) = S_{X} (ξ), F_{2} (ϕ, χ, ψ) (ξ) = I_{X} (ξ), F_{3} (ϕ, χ, ψ) (ξ) = R_{X} (ξ) .

Lemma 5.

The operator F maps

Γ_{X}

into

Γ_{X}

, and is completely continuous.

Proof.

First, by Lemmas 2–4 and using the similar method as that of Theorem 2.4 in [28], we can obtain that F maps

Γ_{X}

into

Γ_{X}

. We leave the proof in the Appendix A. Next, we only give the proof of continuity and compactness of F.

By a direct computation, we can obtain the solutions of the initial value problem (18)–(20) as follows:

\begin{matrix} S_{X} (ξ) & = S_{-} (- X) e^{- \frac{d_{1}}{c} (ξ + X)} + \frac{1}{c} \int_{- X}^{ξ} e^{\frac{d_{1}}{c} (η - ξ)} (d_{1} (J * \tilde{ϕ}) (η) - \frac{β ϕ (η) (G * \tilde{χ}) (η)}{ϕ (η) + (G * \tilde{χ}) (η) + ψ (η)}) d η, \\ I_{X} (ξ) & = I_{-} (- X) e^{- \frac{d_{2} + γ + δ}{c} (ξ + X)} + \frac{1}{c} \int_{- X}^{ξ} e^{\frac{d_{2} + γ + δ}{c} (η - ξ)} (d_{2} (J * \tilde{χ}) (η) + \frac{β ϕ (η) (G * \tilde{χ}) (η)}{ϕ (η) + (G * \tilde{χ}) (η) + ψ (η)}) d η, \\ R_{X} (ξ) & = \frac{1}{c} \int_{- X}^{ξ} e^{\frac{d_{3}}{c} (η - ξ)} (d_{3} (J * \tilde{ψ}) (η) + γ χ (η)) d η . \end{matrix}

For any

(ϕ_{i}, χ_{i}, ψ_{i}) \in Γ_{X}, i = 1, 2

, we denote

F_{1} (ϕ_{i}, χ_{i}, ψ_{i}) (ξ) = S_{X, i} (ξ), F_{2} (ϕ_{i}, χ_{i}, ψ_{i}) (ξ) = I_{X, i} (ξ), F_{3} (ϕ_{i}, χ_{i}, ψ_{i}) (ξ) = R_{X, i} (ξ) .

Since

J * \tilde{ϕ} (η) = \int_{- \infty}^{- X} J (η - y) S_{-} (y) d y + \int_{- X}^{X} J (η - y) ϕ (y) d y + \int_{X}^{\infty} J (η - y) ϕ (X) d y,

we have

| J * {\tilde{ϕ}}_{1} (η) - J * {\tilde{ϕ}}_{2} (η) | \leq 2 max_{y \in [- X, X]} | ϕ_{1} (y) - ϕ_{2} (y) | .

Similarly, there hold

| J * {\tilde{χ}}_{1} (η) - J * {\tilde{χ}}_{2} (η) | \leq 2 max_{y \in [- X, X]} | χ_{1} (y) - χ_{2} (y) |,

| J * {\tilde{ψ}}_{1} (η) - J * {\tilde{ψ}}_{2} (η) | \leq 2 max_{y \in [- X, X]} | ψ_{1} (y) - ψ_{2} (y) |

and

| G * {\tilde{χ}}_{1} (η) - G * {\tilde{χ}}_{2} (η) | \leq 2 max_{y \in [- X, X]} | χ_{1} (y) - χ_{2} (y) | .

By proposition 2.5 in [33], we have that

\frac{β ϕ (η) (G * \tilde{χ}) (η)}{ϕ (η) + (G * \tilde{χ}) (η) + ψ (η)}

is Lipschitz continuous. Then, by the definitions of

S_{X, i} (ξ), I_{X, i} (ξ), R_{X, i} (ξ)

and the operator F, we can conclude that F is continuous.

Finally, we show that F is compact. Since

S_{X} (\cdot)

,

I_{X} (\cdot), R_{X} (\cdot) \in C^{1} ([- X, X])

and satisfy (18)–(20), we obtain that

S_{X}^{'}, I_{X}^{'}

and

R_{X}^{'}

are uniformly bounded. Thus, the operator F is compact, and we obtain that F is completely continuous. □

Based on the above discussion, by using Schauder’s fixed point theorem, we obtain the following result.

Theorem 1.

There exists

(S_{X} (\cdot), I_{X} (\cdot), R_{X} (\cdot)) \in Γ_{X}

such that

(S_{X} (\cdot), I_{X} (\cdot), R_{X} (\cdot)) = F (S_{X}, I_{X}, R_{X}) (ξ) f o r a n y ξ \in (- X, X) .

3.2. Traveling Wave Solution for (6) on $R$

Next, we want to obtain the existence of solutions for traveling wave system (6) on

R

. To this end, we will give some priori estimates for

S_{X}, I_{X}, R_{X}

in the space

C^{1, 1} ([- X, X])

, where

C^{1, 1} ([- X, X]) = {u \in C^{1} ([- X, X]) ∣ u, u^{'} are Lipschitz continuous}

with the norm

{∥ u ∥}_{C^{1, 1} ([- X, X])} = max_{x \in [- X, X]} | u | + max_{x \in [- X, X]} | u^{'} | + sup_{x \neq y \in [- X, X]} \frac{| u^{'} (x) - u^{'} (y) |}{| x - y |} .

Lemma 6.

For any

X > \frac{1}{η} ln M

, there exists

Y > 0

, such that

Y + r < X

, and

∥ S_{X} ∥_{C^{1, 1} ([- Y, Y])} \leq C (Y), ∥ I_{X} ∥_{C^{1, 1} ([- Y, Y])} \leq C (Y), {∥ R_{X} ∥}_{C^{1, 1} ([- Y, Y])} \leq C (Y),

where r is the radius of

s u p p J

,

C (Y)

is a constant which is independent from X.

Proof.

Clearly,

(S_{X}, I_{X}, R_{X})

satisfies

\begin{matrix} c S_{X}^{'} (ξ) & = d_{1} \int_{- \infty}^{\infty} J (ξ - y) {\tilde{S}}_{X} (y) d y - d_{1} S_{X} (ξ) - \frac{β S_{X} (ξ) (G * {\tilde{I}}_{X}) (ξ)}{S_{X} (ξ) + (G * {\tilde{I}}_{X}) (ξ) + R_{X} (ξ)}, \end{matrix}

(22)

\begin{matrix} c I_{X}^{'} (ξ) & = d_{2} \int_{- \infty}^{\infty} J (ξ - y) {\tilde{I}}_{X} (y) d y - (d_{2} + γ + δ) I_{X} (ξ) \\ + \frac{β S_{X} (ξ) (G * {\tilde{I}}_{X}) (ξ)}{S_{X} (ξ) + (G * {\tilde{I}}_{X}) (ξ) + R_{X} (ξ)}, \end{matrix}

(23)

\begin{matrix} c R_{X}^{'} (ξ) & = d_{3} \int_{- \infty}^{\infty} J (ξ - y) {\tilde{R}}_{X} (y) d y - d_{3} R_{X} (ξ) + γ I_{X} (ξ) \end{matrix}

(24)

for

ξ \in [- X, X]

, where

\begin{matrix} {\tilde{S}}_{X} (ξ) = \{\begin{matrix} S_{X} (X), & ξ > X, \\ S_{X} (ξ), & | ξ | \leq X, \\ S_{-} (ξ), & ξ < - X, \end{matrix} {\tilde{I}}_{X} (ξ) = \{\begin{matrix} I_{X} (X), & ξ > X, \\ I_{X} (ξ), & | ξ | \leq X, \\ I_{-} (ξ), & ξ < - X \end{matrix} \end{matrix}

and

\begin{matrix} {\tilde{R}}_{X} (ξ) = \{\begin{matrix} R_{X} (X), & ξ > X, \\ R_{X} (ξ), & | ξ | \leq X, \\ R_{-} (ξ), & ξ < - X . \end{matrix} \end{matrix}

Since

S_{X} (ξ) \leq S_{0}

, we can deduce from equation (22) that

\begin{matrix} | S_{X}^{'} (ξ) | & \leq \frac{1}{c} (d_{1} | J * {\tilde{S}}_{X} (ξ) | + d_{1} | S_{X} (ξ) | + β | \frac{S_{X} (G * {\tilde{I}}_{X})}{S_{X} + (G * {\tilde{I}}_{X}) + R_{X}} |) \\ \leq \frac{2 d_{1} + β}{c} S_{0} . \end{matrix}

(25)

Similarly, we have that

| I_{X}^{'} (ξ) | \leq \frac{2 d_{2} + β + γ + δ}{c} (\frac{β}{γ + δ} - 1) S_{0} .

(26)

Since

R_{X} (ξ) \in Γ_{X}

, combined with the definitions of

Γ_{X}

and

R_{+} (ξ)

, we know that

R_{X} (ξ) \leq M_{1} e^{η Y}

for any

ξ \in [- Y, Y]

, where

0 < Y < X - r

. By formula (24) and using the analogous argument as inequality (25), we can obtain that

| R_{X}^{'} (ξ) | \leq \frac{1}{c} (2 d_{3} M_{1} e^{η Y} + \frac{γ (β - γ - δ)}{γ + δ} S_{0}), ξ \in [- Y, Y] .

Consequently, we can conclude that, for any

ξ, η \in [- Y, Y]

, there exist positive constants

L_{1}, L (Y)

such that,

| S_{X} (ξ) - S_{X} (η) | \leq L_{1} | ξ - η |, | I_{X} (ξ) - I_{X} (η) | \leq L_{1} | ξ - η |, | R_{X} (ξ) - R_{X} (η) | \leq L (Y) | ξ - η | .

Finally, we will prove that

S_{X}^{'} (ξ), I_{X}^{'} (ξ), R_{X}^{'} (ξ)

are Lipschitz continuous. For any

ξ, η \in [- Y, Y]

, it can be inferred from equation (22) that

\begin{matrix} | S_{X}^{'} (ξ) - S_{X}^{'} (η) | & \leq \frac{d_{1}}{c} | \int_{- \infty}^{\infty} [J (ξ - y) - J (η - y)] {\tilde{S}}_{X} (y) d y | + \frac{d_{1}}{c} | S_{X} (ξ) - S_{X} (η) | \\ + \frac{β}{c} | \frac{S_{X} (ξ) (G * {\tilde{I}}_{X}) (ξ)}{S_{X} (ξ) + (G * {\tilde{I}}_{X}) (ξ) + R_{X} (ξ)} - \frac{S_{X} (η) (G * {\tilde{I}}_{X}) (η)}{S_{X} (η) + (G * {\tilde{I}}_{X}) (η) + R_{X} (η)} | \\ : = Λ_{1} + Λ_{2} + Λ_{3} . \end{matrix}

Since

\begin{matrix} | \int_{- X}^{X} [J (ξ - y) - J (η - y)] S_{X} (y) d y | & = | \int_{ξ - X}^{ξ + X} J (y) S_{X} (ξ - y) d y - \int_{η - X}^{η + X} J (y) S_{X} (η - y) d y | \\ = | \int_{ξ - X}^{η - X} J (y) S_{X} (ξ - y) d y + \int_{η - X}^{ξ + X} J (y) S_{X} (ξ - y) d y \\ - \int_{η - X}^{ξ + X} J (y) S_{X} (η - y) d y - \int_{ξ + X}^{η + X} J (y) S_{X} (η - y) d y | \\ \leq (2 S_{0} ∥ J ∥_{L^{\infty}} + L_{1}) | ξ - η |, \end{matrix}

then we can obtain the following estimation about

Λ_{1}

:

\begin{matrix} | \int_{- \infty}^{\infty} [J (ξ - y) - J (η - y)] {\tilde{S}}_{X} (y) d y | \\ = | \int_{- \infty}^{- X} (J (ξ - y) - J (η - y)) S_{-} (y) d y + \int_{- X}^{X} (J (ξ - y) - J (η - y)) S_{X} (y) d y \\ + \int_{X}^{\infty} (J (ξ - y) - J (η - y)) S_{X} (X) d y | \\ \leq S_{0} | \int_{- \infty}^{- X} (J (ξ - y) - J (η - y)) d y | + (2 S_{0} {∥ J ∥}_{L^{\infty}} + L_{1}) | ξ - η | + S_{0} | \int_{X}^{\infty} (J (ξ - y) - J (η - y)) d y | \\ = S_{0} (| \int_{ξ + X}^{η + X} J (y) d y | + | \int_{η - X}^{ξ - X} J (y) d y |) + (2 S_{0} {∥ J ∥}_{L^{\infty}} + L_{1}) | ξ - η | \\ \leq (4 S_{0} ∥ J ∥_{L^{\infty}} + L_{1}) | ξ - η | . \end{matrix}

Moreover, a simple calculation implies that

Λ_{3} \leq \frac{β}{c} [| S_{X} (ξ) - S_{X} (η) | + | G * {\tilde{I}}_{X} (ξ) - G * {\tilde{I}}_{X} (η) | + | R_{X} (ξ) - R_{X} (η) |] .

By a direct calculation, we have

\begin{matrix} | G * {\tilde{I}}_{X} (ξ) - G * {\tilde{I}}_{X} (η) | \\ = | \int_{0}^{T} \int_{- \infty}^{\infty} [G (ξ - y - c s, s) - G (η - y - c s, s)] {\tilde{I}}_{X} (y) d y d s | \\ = | \int_{0}^{T} \int_{- \infty}^{- X} [G (ξ - y - c s, s) - G (η - y - c s, s)] I_{-} (y) d y d s \\ + \int_{0}^{T} \int_{- X}^{X} [G (ξ - y - c s, s) - G (η - y - c s, s)] I_{X} (y) d y d s \\ + \int_{0}^{T} \int_{X}^{\infty} [G (ξ - y - c s, s) - G (η - y - c s, s)] I_{X} (X) d y d s | \\ \leq T L_{G} \int_{- \infty}^{\frac{1}{η} ln \frac{1}{M}} I_{-} (y) d y | ξ - η | + (\frac{β}{γ + δ} - 1) S_{0} \int_{0}^{T} \int_{ξ - X - c s}^{η - X - c s} | G (y, s) | d y d s \\ + | \int_{0}^{T} \int_{- X}^{X} [G (ξ - y - c s, s) - G (η - y - c s, s)] I_{X} (y) d y d s |, \end{matrix}

where

L_{G}

is the Lipschitz constant of kernel

G (y, s)

with invariable y. Since

\begin{matrix} | \int_{0}^{T} \int_{- X}^{X} [G (ξ - y - c s, s) - G (η - y - c s, s)] I_{X} (y) d y d s | \\ \leq | \int_{0}^{T} \int_{η + X - c s}^{ξ + X - c s} G (y, s) I_{X} (ξ - y - c s) d y d s | + | \int_{0}^{T} \int_{η - X - c s}^{ξ - X - c s} G (y, s) I_{X} (η - y - c s) d y d s | \\ + | \int_{0}^{T} \int_{ξ - X - c s}^{η + X - c s} G (y, s) [I_{X} (ξ - y - c s) - I_{X} (η - y - c s)] d y d s | \\ \leq [2 (\frac{β}{δ + γ} - 1) S_{0} T {∥ G ∥}_{L^{\infty} (R \times [0, T])} + L_{1}] | ξ - η |, \end{matrix}

we have

Λ_{3} \leq \frac{β}{c} [2 L_{1} + T L_{G} \int_{- \infty}^{\frac{1}{η} ln \frac{1}{M}} I_{-} (y) d y + 3 (\frac{β}{δ + γ} - 1) S_{0} T {∥ G ∥}_{L^{\infty} (R \times [0, T])} + L (Y)] | ξ - η | .

Thus, there exists a constant

C_{1} (Y)

such that

| S_{X}^{'} (ξ) - S_{X}^{'} (η) | \leq C_{1} (Y) | ξ - η | .

Similarly, there exist two constants

C_{2} (Y), C_{3} (Y)

such that

| I_{X}^{'} (ξ) - I_{X}^{'} (η) | \leq C_{2} (Y) | ξ - η |, | R_{X}^{'} (ξ) - R_{X}^{'} (η) | \leq C_{3} (Y) | ξ - η | .

Therefore, there exists some constant

C (Y) > 0

, such that

∥ S_{X} ∥_{C^{1, 1} ([- Y, Y])} \leq C (Y), ∥ I_{X} ∥_{C^{1, 1} ([- Y, Y])} \leq C (Y), {∥ R_{X} ∥}_{C^{1, 1} ([- Y, Y])} \leq C (Y) .

□

Now, we derive the existence of solutions for system (6) on

R

by a limiting argument. Choose a sequence

{X_{n}}_{n = 1}^{+ \infty}

such that

X_{n} > \frac{1}{η} ln M, X_{n} > Y + r

and

lim_{n \to + \infty} X_{n} = + \infty

. For every n, we know that there exists

(S_{X_{n}}, I_{X_{n}}, R_{X_{n}}) \in Γ_{X_{n}}

satisfying the conclusion in Lemma 6. Therefore, there exists a subsequence

{X_{n_{k}}}

by diagonal extraction argument, such that

lim_{k \to + \infty} X_{n_{k}} = + \infty

and

S_{n_{k}} \to S, I_{n_{k}} \to I, R_{n_{k}} \to R

when

k \to + \infty

.

By (J), (G) and Lebesgue dominated convergence theorem, we obtain

\begin{matrix} lim_{k \to + \infty} \int_{- \infty}^{\infty} J (ξ - y) {\tilde{S}}_{n_{k}} (y) d y & = \int_{- \infty}^{\infty} J (ξ - y) S (y) d y = J * S (ξ), \\ lim_{k \to + \infty} \int_{- \infty}^{\infty} J (ξ - y) {\tilde{I}}_{n_{k}} (y) d y & = \int_{- \infty}^{\infty} J (ξ - y) I (y) d y = J * I (ξ), \\ lim_{k \to + \infty} \int_{- \infty}^{\infty} J (ξ - y) {\tilde{R}}_{n_{k}} (y) d y & = \int_{- \infty}^{\infty} J (ξ - y) R (y) d y = J * R (ξ) \end{matrix}

and

lim_{k \to + \infty} \int_{0}^{\infty} \int_{- \infty}^{\infty} G (ξ - y - c s) {\tilde{I}}_{n_{k}} (y) d y = G * I (ξ) .

Hence,

(S, I, R)

satisfies the traveling wave system (6) with

S_{-} (ξ) < S (ξ) \leq S_{0}, I_{-} (ξ) \leq I (ξ) \leq I_{+} (ξ), 0 < R (ξ) \leq R_{+} (ξ) .

By the definition of

(S_{-} (ξ), I_{-} (ξ), R_{-} (ξ)

and

(S_{+} (ξ), I_{+} (ξ), R_{+} (ξ)

and utilizing squeeze theorem, we have the following existence theorem.

Theorem 2.

Supposing that

R_{0} = \frac{β}{γ + δ} > 1

. For any

c > c^{*}

, there exists

(S (ξ), I (ξ), R (ξ))

, which satisfies the traveling wave system (6) with

S_{-} (ξ) < S (ξ) \leq S_{0}, I_{-} (ξ) \leq I (ξ) \leq I_{+} (ξ), 0 < R (ξ) \leq R_{+} (ξ)

and

S (- \infty) = S_{0}, I (- \infty) = 0, R (- \infty) = 0 .

3.3. Asymptotic Behavior

In the following, we will consider the asymptotic behavior of traveling waves

(S (ξ), I (ξ), R (ξ))

at

+ \infty

. For this purpose, we give some estimations in advance.

Lemma 7.

Suppose that

R_{0} = \frac{β}{γ + δ} > 1

and

c > c^{*}

, then the solution

(S (ξ), I (ξ), R (ξ))

of system (6) satisfies

0 < \int_{- \infty}^{\infty} \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} < + \infty

and

\int_{- \infty}^{\infty} I (ξ) d ξ < + \infty, I (\infty) = 0 .

Proof.

First, due to the positive of

\frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)}

, we get

\int_{- \infty}^{\infty} \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} > 0 .

By using the Fubini theorem, we have that

\begin{matrix} \int_{z}^{x} (J * S (ξ) - S (ξ)) d ξ & = \int_{z}^{x} \int_{- \infty}^{\infty} J (y) (S (ξ - y) - S (ξ)) d y d ξ \\ = - \int_{z}^{x} \int_{- \infty}^{\infty} y J (y) \int_{0}^{1} S^{'} (ξ - θ y) d θ d y d ξ \\ = \int_{- \infty}^{\infty} y J (y) \int_{0}^{1} (S (z - θ y) - S (x - θ y)) d θ d y . \end{matrix}

By assumption (J) and passing a limit above, we have

\begin{matrix} lim_{z \to - \infty} \int_{z}^{x} (J * S (ξ) - S (ξ)) d ξ & = \int_{- \infty}^{\infty} y J (y) \int_{0}^{1} (S_{0} - S (x - θ y)) d θ d y \\ = - \int_{- \infty}^{\infty} y J (y) \int_{0}^{1} S (x - θ y)) d θ d y, \end{matrix}

which implies that, for

x \in R

,

| \int_{- \infty}^{x} (J * S (ξ) - S (ξ)) d ξ | \leq S_{0} \int_{- \infty}^{\infty} | y | J (y) d y : = ϱ_{1} .

(27)

Integrating the first equation of system (6) from

- \infty

to x and using formula (27) yields

\begin{matrix} \int_{- \infty}^{x} \frac{β S (ξ) (G * \tilde{I}) (ξ)}{S (ξ) + (G * \tilde{I}) (ξ) + R (ξ)} d ξ & = d_{1} \int_{- \infty}^{x} (J * S (ξ) - S (ξ) d ξ + c [S_{0} - S (x)] \\ \leq d_{1} ϱ_{1} + c S_{0} . \end{matrix}

Then, we conclude that

\int_{- \infty}^{\infty} \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} < \infty .

(28)

Through a similar calculation as inequality (27), we have

| \int_{- \infty}^{x} (J * I (ξ) - I (ξ)) d ξ | \leq (\frac{β - γ - δ}{γ + δ}) S_{0} \int_{- \infty}^{\infty} | y | J (y) d y : = ϱ_{2} .

(29)

Integrating the second equation of system (6) from

- \infty

to ∞ and using Formulas (28) and (29), we have

\begin{matrix} c I (\infty) + (γ + δ) \int_{R} I (ξ) d ξ & = d_{2} \int_{R} (J * I (ξ) - I (ξ)) d ξ \\ + \int_{R} \frac{β S (ξ) (G * \tilde{I}) (ξ)}{S (ξ) + (G * \tilde{I}) (ξ) + R (ξ)} d ξ \\ < \infty . \end{matrix}

Hence, we conclude that

\int_{- \infty}^{\infty} I (ξ) d ξ < \infty

. Combined with the claim obtained before that

I^{'} (ξ)

is bounded on

R

, we have that

I (\infty) = 0

. □

Theorem 3.

Assuming that

R_{0} = \frac{β}{γ + δ} > 1

and

c > c^{*}

, then

(1): $lim_{ξ \to + \infty} S (ξ)$ exists and $S_{\infty} : = lim_{ξ \to + \infty} S (ξ) < S_{0}$ ;
(2): If $lim_{ξ \to + \infty} sup R (ξ) < \infty$ , then $lim_{ξ \to + \infty} R (ξ) = \frac{γ (S_{0} - S_{\infty})}{γ + δ}$ .

Proof.

First, we prove the existence of

lim_{ξ \to + \infty} S (ξ)

. On the contrary, we assume that

lim_{ξ \to + \infty} inf S (ξ) = m_{1} < lim_{ξ \to + \infty} sup S (ξ) = m_{2} .

Thus, we can find two point sequences

{ξ_{n}}

and

{η_{n}}

such that

\begin{matrix} lim_{n \to + \infty} S (ξ_{n}) = lim inf_{ξ \to + \infty} S (ξ) = m_{1}, S^{'} (ξ_{n}) = 0, \\ lim_{n \to + \infty} S (η_{n}) = lim sup_{ξ \to + \infty} S (ξ) = m_{2}, S^{'} (η_{n}) = 0, \\ lim_{n \to + \infty} J * S (ξ_{n}) \geq m_{1}, lim_{n \to + \infty} J * S (η_{n}) \leq m_{2} . \end{matrix}

Following the first equation of system (6), we have

0 = c S^{'} (ξ_{n}) = d_{1} (J * S (ξ_{n}) - S (ξ_{n})) - \frac{β S (ξ_{n}) (G * I) (ξ_{n})}{S (ξ_{n}) + (G * I) (ξ_{n}) + R (ξ_{n})} .

Letting

n \to + \infty

, we can obtain that

lim_{n \to + \infty} J * S (ξ_{n}) = lim_{n \to + \infty} S (ξ_{n}) = m_{1}

. We prove that

S (ξ_{n} - z) \to m_{1}

as

n \to + \infty

for any

z \in s u p p J : = Ω

. Choose a sufficiently small

ϵ > 0

, let

{\tilde{S}}_{n} (z) = S (ξ_{n} - z)

and

Ω_{ϵ} = Ω \cap {z | lim_{n \to + \infty} \tilde{S} (z) > m_{1} + ϵ}

. Hence, we have

\begin{matrix} m_{1} & = lim_{n \to + \infty} J * S (ξ_{n}) = lim_{n \to + \infty} \int_{Ω} J (z) {\tilde{S}}_{n} (z) d z \\ \geq \underset{n \to + \infty}{lim inf} \int_{Ω ∖ Ω_{ϵ}} J (z) {\tilde{S}}_{n} (z) d z + \underset{n \to + \infty}{lim inf} \int_{Ω_{ϵ}} J (z) {\tilde{S}}_{n} (z) d z \\ \geq m_{1} \int_{Ω ∖ Ω_{ϵ}} J (z) d z + (m_{1} + ϵ) \int_{Ω_{ϵ}} J (z) d z \\ = m_{1} + ϵ \int_{Ω_{ϵ}} J (z) d z, \end{matrix}

which yields that

μ (I_{ϵ}) = 0

where

μ (\cdot)

denotes the measure. Thus, we have for any

z \in Ω

,

S (ξ_{n} - z) \to m_{1}, a . e . n \to + \infty .

(30)

On the other hand, we have

0 = c S^{'} (η_{n}) = d_{1} (J * S (η_{n}) - S (η_{n})) - \frac{β S (η_{n}) (G * I) (η_{n})}{S (η_{n}) + (G * I) (η_{n}) + R (η_{n})};

then, letting

n \to + \infty

, by

I (+ \infty) = 0

, we can obtain that

lim_{n \to + \infty} J * S (η_{n}) = lim_{n \to + \infty} S (ξ_{n}) = m_{2} > m_{1} .

Then, by a similar discussion to formula (30), we can get that, for any

z \in Ω

,

S (η_{n} - z) \to m_{2}, a . e . n \to + \infty .

Note that, when

n \to + \infty

,

\int_{ξ_{n}}^{η_{n}} \frac{β S (ξ) G * I (ξ)}{S (ξ) + G * I (ξ) + R (ξ)} d ξ \to 0 .

Integrating the first equation of system (6) from

ξ_{n}

to

η_{n}

, we have

\begin{matrix} 0 & < c (m_{2} - m_{1}) \\ = d_{1} lim_{n \to + \infty} \int_{ξ_{n}}^{η_{n}} (J * S (ξ) - S (ξ)) d ξ - lim_{n \to + \infty} \int_{ξ_{n}}^{η_{n}} \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} d ξ \\ = d_{1} lim_{n \to + \infty} \int_{- \infty}^{\infty} y J (y) \int_{0}^{1} [S (ξ_{n} - t y) - S (η_{n} - t y)] d t d y \\ = d_{1} (m_{1} - m_{2}) \int_{- \infty}^{\infty} y J (y) d y = 0, \end{matrix}

which leads to a contradiction. Therefore,

lim_{ξ \to + \infty} inf S (ξ) = lim_{ξ \to + \infty} sup S (ξ),

which implies that

lim_{ξ \to + \infty} S (ξ) = : S_{\infty}

exists.

Next, we will derive that

S_{\infty} < S_{0}

. Since

S (ξ) \leq S_{0}

, then

S_{\infty} \leq S_{0}

. We assume, on the contrary, that

S_{\infty} = S_{0}

. Integrating the first equation of system (6) from

- x

to x yields

\begin{matrix} c [S (x) - S (- x)] & = d_{1} \int_{- \infty}^{\infty} y J (y) \int_{0}^{1} (S (- x - t y) - S (x - t y)) d t d y \\ - \int_{- x}^{x} \frac{β S (ξ) G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} d ξ . \end{matrix}

Letting

x \to + \infty

, we have

\int_{- \infty}^{\infty} \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} d ξ = 0,

which leads to a contradiction. Thus, we have

S_{\infty} < S_{0}

.

Using the similar method above, we can obtain that, when

lim_{ξ \to + \infty} sup R (ξ) < + \infty

,

lim_{ξ \to + \infty} R (ξ) : = R_{\infty}

. Now, integrating the first equation of system (6) on

R

yields that

\int_{- \infty}^{\infty} \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} d ξ = c (S_{0} - S_{\infty}) .

By integrating the second and third equation of system (6) on

R

, we can obtain that

\begin{matrix} (γ + δ) \int_{- \infty}^{\infty} I (ξ) d ξ = \int_{- \infty}^{\infty} \frac{β S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} d ξ, \\ c R_{\infty} = γ \int_{- \infty}^{\infty} I (ξ) d ξ . \end{matrix}

Therefore,

R_{\infty} = \frac{γ (S_{0} - S_{\infty})}{γ + δ} .

□

4. Nonexistence of Traveling Waves

In this section, we will study the nonexistence of traveling wave solutions for system (5).

Theorem 4.

Suppose that

R_{0} > 1

and

0 < c < c^{*}

, then system (5) has no nontrivial positive solution

(S, I, R)

that satisfies the following asymptotic boundary conditions:

S (- \infty) = S_{0}, sup_{R} S (x) \leq S_{0}, I (\pm \infty) = 0, R (- \infty) = 0, sup_{R} R (x) < + \infty .

(31)

Proof.

Assume that

(S (ξ), I (ξ), R (ξ))

is a nontrivial positive solution of system (6) satisfying formula (31). By formula (31), we have

\frac{β S (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} \to β, ξ \to - \infty

. By using the continuity and

R_{0} > 1

, we have that there exists

ξ^{*}

such that, for any

ξ < ξ^{*}

,

\frac{β S (x)}{S (x) + (G * I) (x) + R (x)} > \frac{β + γ + δ}{2} .

Then, for

ξ < ξ^{*}

, it follows from the second equation of (6) that

\begin{matrix} c I^{'} (ξ) & \geq d_{2} [J * I (ξ) - I (ξ)] + \frac{β + γ + δ}{2} (G * I) (ξ) - (γ + δ) I (ξ) \\ = d_{2} [J * I (ξ) - I (ξ)] + \frac{β + γ + δ}{2} [G * I (ξ) - I (ξ)] + \frac{β - γ - δ}{2} I (ξ) . \end{matrix}

(32)

Integrating equation (32) from

- \infty

to

ξ < ξ^{*}

, we get

\begin{matrix} c [I (ξ) - I (- \infty)] & \geq d_{2} \int_{- \infty}^{ξ} [J * I (τ) - I (τ)] d τ + \frac{β - γ - δ}{2} \int_{- \infty}^{ξ} I (τ) d τ \\ + \frac{β + γ + δ}{2} \int_{- \infty}^{ξ} [G * I (τ) - I (τ)] d τ . \end{matrix}

(33)

Denote

K (ξ) = \int_{- \infty}^{ξ} I (τ) d τ, ξ \in R

. It is obvious that

K (- \infty) = 0

and

K (ξ)

is bounded for any

ξ \in R

. By making use of the Fubini theorem, we have

\begin{matrix} \int_{- \infty}^{ξ} J * I (τ) d τ & = \int_{- \infty}^{ξ} \int_{- \infty}^{\infty} J (y) I (τ - y) d y d τ = \int_{- \infty}^{\infty} J (y) \int_{- \infty}^{ξ - y} I (z) d z d y \\ = \int_{- \infty}^{\infty} J (y) K (ξ - y) d y = J * K (ξ), \\ \int_{- \infty}^{ξ} G * I (τ) d τ & = \int_{- \infty}^{ξ} \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) I (τ - y - c s) d y d s d τ \\ = \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) \int_{- \infty}^{ξ - y - c s} I (z) d z d y d s \\ = \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) K (ξ - y - c s) d y d s = G * K (ξ), \end{matrix}

then by formula (33) and

I (- \infty) = 0

, we can obtain that

\frac{β - γ - δ}{2} K (ξ) \leq c I (ξ) - d_{2} [J * K (ξ) - K (ξ)] - \frac{β + γ + δ}{2} [G * K (ξ) - K (ξ)] .

(34)

Integrating Equation (34) from

- \infty

to

ξ < ξ^{*}

, we have

\begin{matrix} \frac{β - γ - δ}{2} \int_{- \infty}^{ξ} K (τ) d τ & \leq c \int_{- \infty}^{ξ} I (τ) d τ - d_{2} \int_{- \infty}^{ξ} [J * K (τ) - K (τ)] d τ \\ - \frac{β + γ + δ}{2} \int_{- \infty}^{ξ} [G * K (τ) - K (τ)] d τ . \end{matrix}

(35)

By calculation, we get

\begin{matrix} \int_{- \infty}^{ξ} [J * K (τ) - K (τ)] d τ & = \int_{- \infty}^{ξ} \int_{- \infty}^{\infty} J (y) [K (τ - y) - K (τ)] d y d τ \\ = \int_{- \infty}^{\infty} J (y) \int_{- \infty}^{ξ} [K (τ - y) - K (τ)] d τ d y \\ = - \int_{- \infty}^{\infty} \int_{0}^{1} y J (y) K (ξ - θ y) d θ d y . \end{matrix}

Similarly,

\int_{- \infty}^{ξ} [G * K (τ) - K (τ)] d τ = - \int_{0}^{\infty} \int_{- \infty}^{\infty} \int_{0}^{1} (y + c s) G (y, s) K (ξ - θ (y + c s)) d θ d y d s .

Thus, formula (35) is equivalent to

\begin{matrix} \frac{β - γ - δ}{2} \int_{- \infty}^{ξ} K (τ) d τ & \leq c K (ξ) + d_{2} \int_{- \infty}^{\infty} \int_{0}^{1} y J (y) K (ξ - θ y) d θ d y \\ + \frac{β + γ + δ}{2} \int_{0}^{\infty} \int_{- \infty}^{\infty} \int_{0}^{1} (y + c s) G (y, s) K (ξ - θ (y + c s)) d θ d y d s . \end{matrix}

Since

y K (ξ - θ y)

is monotone decreasing with respect to

θ \in [0, 1]

, we have

y K (ξ - θ y) \leq y K (ξ)

and

(y + c s) K (ξ - θ (y + c s)) \leq (y + c s) K (ξ)

. Then, we obtain

\begin{matrix} \frac{β - γ - δ}{2} \int_{- \infty}^{ξ} K (τ) d τ & \leq c K (ξ) + d_{2} \int_{- \infty}^{\infty} y J (y) K (ξ) d y \\ + \frac{β + γ + δ}{2} \int_{0}^{\infty} \int_{- \infty}^{\infty} (y + c s) G (y, s) K (ξ) d y d s \\ = c [1 + \frac{β + γ + δ}{2} \int_{0}^{\infty} \int_{- \infty}^{\infty} s G (y, s) d y d s] K (ξ) : = \tilde{L} K (ξ) . \end{matrix}

(36)

Furthermore, since

K (\cdot)

is nondecreasing, and by using formula (36), we can obtain that there exists some

ω > 0

such that

K (ξ - ω) < 1 / 2 K (ξ)

.

For

μ_{0} \in (0, λ_{1})

, define

P (ξ) = K (ξ) e^{- μ_{0} ξ}

. Then, there exists

μ_{0}

such that

P (ξ - ω) < P (ξ)

. Thus,

P (ξ)

is bounded as

ξ \to - \infty

, which infers that there exists a constant

K_{0} > 0

such that

K (ξ) \leq K_{0} e^{μ_{0} ξ}

for all

ξ \in R

. By the definition of

K (ξ)

, we have

sup_{ξ \in R} {I (ξ) e^{- μ_{0} ξ}} < \infty .

Similarly, from the assumptions (J) and (G), we can obtain that

J * I (ξ) e^{- μ_{0} ξ} < \infty, G * I (ξ) e^{- μ_{0} ξ} < \infty .

Moreover, by the second equation of system (6), we can obtain that

I^{'} (ξ) e^{- μ_{0} ξ} < + \infty

for any

ξ \in R

. That is, we have

sup_{ξ \in R} {J * I (ξ) e^{- μ_{0} ξ}} < \infty, sup_{ξ \in R} {G * I (ξ) e^{- μ_{0} ξ}} < \infty, sup_{ξ \in R} {I^{'} (ξ) e^{- μ_{0} ξ}} < \infty .

For any

ξ \in R

, it follows from the second equation of system (6) that

\begin{matrix} d_{2} [J * I (ξ) - I (ξ)] - c I^{'} (ξ) + β (G * I) (ξ) - (γ + δ) I (ξ) = β [G * I (ξ) - \frac{S (x) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)}] . \end{matrix}

(37)

For any

λ \in C

with

0 < R e λ < μ_{0}

, taking a two-sided Laplace transform of

I (ξ)

on Equation (37), we have

Δ (λ, c) L (λ) = β \int_{- \infty}^{\infty} \frac{e^{- λ ξ} [{(G * I)}^{2} (ξ) + (G * I) (ξ) R (ξ)]}{S (ξ) + (G * I) (ξ) + R (ξ)} d ξ,

(38)

where

L (λ) = \int_{- \infty}^{\infty} e^{- λ ξ} I (ξ) d ξ

. Using the property of Laplace transform, we know that either there exists positive constant

λ_{0}

such that

L (λ)

is analytic for

λ \in C

with

0 < R e λ < λ_{0}

and has singularity at

λ = λ_{0}

or for

λ \in C

with

R e λ > 0, L (λ)

is well defined. According to the previous discussion, we know that the integral term on the right-hand side of formula (38) is uniformly bounded on the real line. Then, the two-sided Laplace integrals can be analytically continued to the whole right half plane. By Lemma 1,

Δ (λ, c) > 0

for all

λ > 0

when

0 < c < c^{*}

, thus

L (λ)

is analytic in the right half plane. According to the definition of

Δ (λ, c)

, we know that

Δ (λ, c) \to + \infty

as

λ \to + \infty

, which leads to a contradiction from formula (38). Thus, the conclusion follows.

Theorem 5.

Assume that

R_{0} \leq 1

. For any

c > 0

, system (5) has no nontrivial positive traveling wave solution

(S, I, R)

satisfying formula (31).

Proof.

On the contrary, we suppose that system (5) has a traveling wave solution

(S, I, R)

satisfying formula (31). For the case

R_{0} < 1

, integrating the second equation of system (6) on

R

, we have

(γ + δ) \int_{- \infty}^{\infty} I (ξ) d ξ \leq d_{2} \int_{- \infty}^{\infty} (J * I (ξ) - I (ξ)) d ξ + β \int_{- \infty}^{\infty} I (ξ) d ξ,

that is

\int_{- \infty}^{\infty} I (ξ) d ξ \leq \frac{d_{2}}{γ + δ + d_{2} - β} \int_{- \infty}^{\infty} J * I (ξ) d ξ < \int_{- \infty}^{\infty} I (ξ) d ξ,

which is a contradiction and the assumption does not hold.

When

R_{0} = 1

that is

β = γ + δ

,

c I^{'} (ξ) = d_{2} (J * I (ξ) - I (ξ)) + β [\frac{S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} - I (ξ)] .

Then, integrating the above equation, we have

\int_{- \infty}^{\infty} [\frac{S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} - I (ξ)] d ξ = 0 .

Due to the continuity and nonnegativity of

S, I, R

, we can obtain that

\begin{matrix} 0 & = \int_{- \infty}^{\infty} [\frac{S (ξ) (G * I) (ξ)}{S (ξ) + (G * I) (ξ) + R (ξ)} - I (ξ)] d ξ \\ < \int_{- \infty}^{\infty} G * I (ξ) d ξ - \int_{- \infty}^{\infty} I (ξ) d ξ \\ = \int_{0}^{\infty} \int_{- \infty}^{\infty} G (y, s) \int_{- \infty}^{\infty} I (ξ - y - c s) d ξ d y d s - \int_{- \infty}^{\infty} I (ξ) d ξ \\ = 0, \end{matrix}

which is also a contradiction and completes the proof.

5. Conclusions and Discussion

In this paper, we have studied the existence and nonexistence of nontrivial traveling wave solutions for system (5). Combined with Theorems 2, 4 and 5, we obtain the threshold condition for the existence and nonexistence of traveling wave solutions, which is determined by the basic reproduction number

R_{0}

of the corresponding reaction system and the minimal wave speed

c^{*}

. From Lemma 1, we know that the minimal wave speed

c^{*}

is the unique root of the algebraic equations

Δ (λ, c) = 0, \frac{\partial Δ (λ, c)}{\partial λ} = 0 for λ > 0, c > 0,

where

Δ (λ, c) = d_{2} (\int_{- \infty}^{\infty} J (y) e^{- λ y} d y - 1) - c λ + β \int_{0}^{\infty} \int_{- \infty}^{+ \infty} G (y, s) e^{- λ (y + c s)} d y d s - γ - δ .

It is obvious that the minimal wave speed

c^{*}

is dependent on the dispersal rate

d_{2}

, the pattern of nonlocal interaction between the infected and the susceptible individuals, and the latent period of disease. In order to see the quantitative effect of nonlocal interaction and time delay on the minimum wave speed, we let

G (y, s) = δ (s - τ) \frac{1}{\sqrt{4 π ϱ}} e^{- \frac{y^{2}}{4 ϱ}}

with

τ > 0, ϱ > 0

and

δ (\cdot)

be the Dirac function. By simple calculation, we have

Δ (λ, c) = d_{2} (\int_{- \infty}^{\infty} J (y) e^{- λ y} d y - 1) - c λ + β e^{ϱ λ^{2} - c λ τ} - γ - δ .

Utilizing the implicit function theorem, we have

\begin{matrix} \frac{d c^{*}}{d d_{2}} & = \frac{\int_{R} J (y) e^{- λ^{*} y} d y - 1}{λ^{*} + β λ^{*} τ e^{ϱ λ^{* 2} - c^{*} λ^{*} τ}} > 0, \\ \frac{d c^{*}}{d τ} & = \frac{- β c^{*} λ^{*} e^{ϱ λ^{* 2} - c^{*} λ^{*} τ}}{λ^{*} + β λ^{*} τ e^{ϱ λ^{* 2} - c^{*} λ^{*} τ}} < 0, \\ \frac{d c^{*}}{d ϱ} & = \frac{β λ^{* 2} e^{ϱ λ^{* 2} - c^{*} λ^{*} τ}}{λ^{*} + β λ^{*} τ e^{ϱ λ^{* 2} - c^{*} λ^{*} τ}} > 0 . \end{matrix}

Hence, we conclude that the dispersal rate

d_{2}

and the nonlocal interaction can increase the minimal wave speed, while time delay can reduce the minimal wave speed.

Author Contributions

Both authors contributed equally and significantly in writing this paper. Both authors read and approved the final manuscript.

Funding

This work was partially supported by the National Natural Science Foundation of China (11661017); the Anhui Provincial Natural Science Foundation (1708085QA13); the Science Technology Foundation of Guizhou Province ([2015] 2036); the Natural Science Foundation of Anhui Provincial Education Department (KJ2016A517, KJ2018A0578); the Outstanding Young Talents Project of Anhui Provincial Universities (gxgwfx2018081); and the Teaching Team of Chizhou University (2018XJXTD03).

Acknowledgments

The authors thanks anonymous referees for their remarkable comments, suggestion, and ideas that help to improve this paper.

Conflicts of Interest

The authors declare no conflict of interest.

Appendix A

In this appendix, we will prove the conclusion that F maps

Γ_{X}

into

Γ_{X}

in Lemma 5. For any

(ϕ (\cdot), χ (\cdot), ψ (\cdot)) \in Γ_{X}

, we will prove that, for any

ξ \in [- X, X]

,

\begin{matrix} S_{-} (ξ) & \leq F_{1} (ϕ, χ, ψ) (ξ) \leq S_{0}; \end{matrix}

(A1)

\begin{matrix} I_{-} (ξ) & \leq F_{2} (ϕ, χ, ψ) (ξ) \leq I_{+} (ξ); \end{matrix}

(A2)

\begin{matrix} R_{-} (ξ) & \leq F_{3} (ϕ, χ, ψ) (ξ) \leq R_{+} (ξ) . \end{matrix}

(A3)

From the definition of

\tilde{ϕ} (ξ)

and

Γ_{X}

, we can calculate that

\begin{matrix} d_{1} \int_{R} J (y) \tilde{ϕ} (ξ - y) d y - d_{1} S_{0} - \frac{β ϕ (ξ) (G * \tilde{φ}) (ξ)}{ϕ (ξ) + (G * \tilde{φ}) (ξ) + ψ (ξ)} \\ \leq d_{1} S_{0} - d_{1} S_{0} - \frac{β ϕ (ξ) (G * \tilde{φ}) (ξ)}{ϕ (ξ) + (G * \tilde{φ}) (ξ) + ψ (ξ)} \\ \leq 0 . \end{matrix}

Since

F_{1} (ϕ, φ, ψ) (ξ) = S_{X} (ξ)

and

S_{X} (ξ)

satisfies (18), by using the maximum principle, we have that

S_{X} (ξ) \leq S_{0}

for

ξ \in [- X, X]

.

On the other hand, for

S_{-} (ξ) = S_{0} (1 - σ e^{α ξ})

, by using Lemma 3, we can obtain that

\begin{matrix} c S_{-}^{'} (ξ) - d_{1} \int_{R} J (y) \tilde{ϕ} (ξ - y) d y + d_{1} S_{-} (ξ) + \frac{β ϕ (ξ) (G * \tilde{φ}) (ξ)}{ϕ (ξ) + (G * \tilde{φ}) (ξ) + ψ (ξ)} \\ \leq c S_{-}^{'} (ξ) - d_{1} \int_{R} J (y) S_{-} (ξ - y) d y + d_{1} S_{-} (ξ) + \frac{β ϕ (ξ) (G * \tilde{φ}) (ξ)}{ϕ (ξ) + (G * \tilde{φ}) (ξ) + ψ (ξ)} \\ \leq c S_{-}^{'} (ξ) - d_{1} \int_{R} J (y) S_{-} (ξ - y) d y + d_{1} S_{-} (ξ) + \frac{β S_{-} (ξ) (G * I_{+} (ξ)}{S_{-} (ξ) + (G * I_{+} φ) (ξ) + R_{-} (ξ)} \\ \leq 0 . \end{matrix}

Using the maximum principle again, we have that

S_{-} (ξ) \leq S_{X} (ξ)

for all

ξ \in [- X, X]

. It is concluded that

S_{-} (ξ) \leq F_{1} (ϕ, χ, ψ) (ξ) \leq S_{0}

for

ξ \in [- X, X]

.

Similarly, we can obtain that (A2)–(A3) hold. Thus, F maps

Γ_{X}

into

Γ_{X}

.

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Wu, K.; Zhou, K. Traveling Waves in a Nonlocal Dispersal SIR Model with Standard Incidence Rate and Nonlocal Delayed Transmission. Mathematics 2019, 7, 641. https://doi.org/10.3390/math7070641

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Wu K, Zhou K. Traveling Waves in a Nonlocal Dispersal SIR Model with Standard Incidence Rate and Nonlocal Delayed Transmission. Mathematics. 2019; 7(7):641. https://doi.org/10.3390/math7070641

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Wu, Kuilin, and Kai Zhou. 2019. "Traveling Waves in a Nonlocal Dispersal SIR Model with Standard Incidence Rate and Nonlocal Delayed Transmission" Mathematics 7, no. 7: 641. https://doi.org/10.3390/math7070641

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Traveling Waves in a Nonlocal Dispersal SIR Model with Standard Incidence Rate and Nonlocal Delayed Transmission

Abstract

1. Introduction

2. Some Preliminaries

3. Existence of Traveling Waves

3.1. Upper-Lower Solution of System (6)

3.2. Traveling Wave Solution for (6) on $R$

3.3. Asymptotic Behavior

4. Nonexistence of Traveling Waves

5. Conclusions and Discussion

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

Appendix A

References

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Traveling Waves in a Nonlocal Dispersal SIR Model with Standard Incidence Rate and Nonlocal Delayed Transmission

Abstract

1. Introduction

2. Some Preliminaries

3. Existence of Traveling Waves

3.1. Upper-Lower Solution of System (6)

3.2. Traveling Wave Solution for (6) on R

3.3. Asymptotic Behavior

4. Nonexistence of Traveling Waves

5. Conclusions and Discussion

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

Appendix A

References

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Further Information

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3.2. Traveling Wave Solution for (6) on $R$