Global dynamics in a stochastic three species food-chain model with harvesting and distributed delays

Tuerxun, Nafeisha; Teng, Zhidong; Muhammadhaji, Ahmadjan

doi:10.1186/s13662-019-2122-4

Research
Open access
Published: 15 May 2019

Global dynamics in a stochastic three species food-chain model with harvesting and distributed delays

Nafeisha Tuerxun¹,
Zhidong Teng¹ &
Ahmadjan Muhammadhaji¹

Advances in Difference Equations volume 2019, Article number: 187 (2019) Cite this article

1070 Accesses
10 Citations
Metrics details

Abstract

This paper proposes a stochastic three species food-chain model with harvesting and distributed delays. Some criteria for the global dynamics of all positive solutions, including the existence of global positive solutions, stochastic boundedness, extinction, global asymptotic stability in the mean, and the probability distribution, are established by using the stochastic integral inequalities, Lyapunov function method, and the inequality estimation technique. Furthermore, the effects of harvesting are discussed, the optimal harvesting strategy and the maximum of expectation of sustainable yield (MESY for short) are obtained. Finally, numerical examples are carried out to illustrate our main results.

1 Introduction

The notion of food-chain was first postulated by Eiton in 1927 (see [1]). As he said, he proposed this idea due to the Chinese folk-adage: big fish eat small fish, small fish eat shrimps, shrimps eat mud. We see that food-chain models have been extensively studied because of their academic and pragmatic implication. The following deterministic three species food-chain model has been investigated by many scholars (see [2,3,4,5]):

$$ \textstyle\begin{cases} \frac{\mathrm{d}x_{1}(t)}{\mathrm{d}t}= x_{1}(t)[r_{1}-a_{11}x_{1}(t)-a _{12}x_{2}(t)],\\ \frac{\mathrm{d}x_{2}(t)}{\mathrm{d}t}=x_{2}(t)[-r_{2}+a _{21}x_{1}(t)-a_{22}x_{2}(t)-a_{23}x_{3}(t)],\\ \frac{\mathrm{d}x_{3}(t)}{ \mathrm{d}t}=x_{3}(t)[-r_{3}+a_{32}x_{2}(t)-a_{33}x_{3}(t)], \end{cases} $$

where $x_{i}(t)$ ($i=1,2,3$) represents population sizes of prey, intermediate predator, and top predator at time t, respectively.

Nevertheless, in the real world, it is hard to protect population systems from environmental noise (see [6,7,8,9,10,11,12,13,14,15]). Taking the influence of white noises into the above model, Liu and Bai in [16] proposed the following stochastic three species food-chain model:

$$ \textstyle\begin{cases} \mathrm{d}x_{1}(t)=x_{1}(t)[r_{1}-h_{1}-a_{11}x_{1}(t)-a_{12}x_{2}(t)]\,\mathrm{d}t+ \sigma _{1}x_{1}(t)\,\mathrm{d}B_{1}(t),\\ \mathrm{d}x_{2}(t)=x_{2}(t)[-r _{2}-h_{2}+a_{21}x_{1}(t)-a_{22}x_{2}(t)-a_{23}x_{3}(t)]\,\mathrm{d}t+\sigma _{2}x _{2}(t)\,\mathrm{d}B_{2}(t),\\ \mathrm{d}x_{3}(t)=x_{3}(t)[-r_{3}-h_{3}+a _{32}x_{2}(t)-a_{33}x_{3}(t)]\,\mathrm{d}t+\sigma _{3}x_{3}(t)\,\mathrm{d}B_{3}(t). \end{cases} $$

Time-delay is common and inevitable in nature, and often makes the system property decline or even causes instability. However, any species in nature will not always react at once to variation in its own population size or that of an interacting species, but will do so after a time lag preferably. In other words, it is essential to investigate the effect of delays on the food-chain model. Thus, Li and Wang in [17] proposed a delayed food-chain system with the Beddington–DeAngelis functional response, and they found that delays affect the stability of equilibrium points and the existence of Hopf bifurcation.

From [18, 19], we obtain that systems with distributed time delays include those not only with the discrete time delays but also the continuously distributed time delays. To the best of our knowledge to date, the problem of a stochastic food-chain model with harvesting and distributed delays has not been studied in the past research. Motivated by the above discussion, considering distributed time delays and white noises, in this paper, we establish the following stochastic three species food-chain model:

$$ \textstyle\begin{cases} \mathrm{d}x_{1}(t)= x_{1}(t)[r_{1}-h_{1}-a_{11}x_{1}(t)-a_{12}\int _{-\tau _{12}} ^{0}x_{2}(t+ \theta )\,\mathrm{d}\mu _{12}(\theta )]\,\mathrm{d}t \\ \hphantom{\mathrm{d}x_{1}(t)=}{}+\sigma _{1}x_{1}(t)\,\mathrm{d}B_{1}(t), \\ \mathrm{d}x_{2}(t)= x_{2}(t)[-r_{2}-h_{2}+a_{21}\int _{-\tau _{21}}^{0}x_{1}(t+\theta ) \,\mathrm{d}\mu _{21}(\theta )-a_{22}x_{2}(t)\\ \hphantom{\mathrm{d}x_{2}(t)=}{} -a_{23}\int _{-\tau _{23}}^{0}x_{3}(t+\theta )\,\mathrm{d}\mu _{23}(\theta )] \,\mathrm{d}t+\sigma _{2}x_{2}(t)\,\mathrm{d}B_{2}(t),\\ \mathrm{d}x_{3}(t)= x_{3}(t)[-r_{3}-h_{3}+a_{32}\int _{-\tau _{32}}^{0}x_{2}(t+ \theta )\,\mathrm{d}\mu _{32}(\theta )-a_{33}x_{3}(t)]\,\mathrm{d}t \\ \hphantom{\mathrm{d}x_{3}(t)=}{}+\sigma _{3}x _{3}(t)\,\mathrm{d}B_{3}(t), \end{cases} $$

(1)

where $r_{1}>0$ is intrinsic growth rate of species $x_{1}$, $r_{i}>0$ ($i=2,3$) stand for death rates of species $x_{i}$, $a_{ii}>0$ ($i=1,2,3$) are intraspecific competition coefficients of species $x_{i}$, $a_{12}\geq 0$ and $a_{23}\geq 0$ are capture rates, $a_{21}\geq 0$ and $a_{32}\geq 0$ measure efficiency of food conversion, $h_{i}\geq 0$ ($i=1,2,3$) stands for the harvesting effort of species $x_{i}$, $\mu _{ij}(\theta )$ ($i,j=1,2,3$) are nonnegative variation functions defined on $[-\tau _{ij},0]$ satisfying $\int _{-\tau _{ij}} ^{0}\mathrm{d}\mu _{ij}(\theta )=1$, $B_{i}(t)$ ($i=1,2,3$) are standard independent Brownian motions defined on the complete probability space $(\varOmega ,\{\mathcal{F}_{t}\}_{t\geq 0},P)$ with a filtration $\{\mathcal{F}_{t}\}_{t\geq 0}$ satisfying the usual conditions, and $\sigma _{i}^{2}$ ($i=1,2,3$) is the intensity of $B_{i}(t)$.

In this paper we firstly investigate the global dynamics of model (1), including the existence of global positive solutions, stochastic boundedness, extinction, global asymptotic stability in the mean, and the probability distribution, by using the stochastic integrals inequalities, Lyapunov function method, and the inequality estimation technique. Next, we discuss the effects of harvesting for the extinction and persistence of species of model (1), and establish the optimal harvesting effort $H^{*}=(h_{1}^{*},h_{2}^{*},h _{3}^{*})$ such that all the species are not extinct and the maximal expectation of sustained yield $Y(H^{*})=\lim_{t\to \infty }\sum_{i=1} ^{3}E(h^{*}_{i}x_{i}(t))$.

The organization of this paper is as follows. In Sect. 2, we propose some useful lemmas which will be used in the proofs of main results. We also obtain the existence and stochastic boundedness of unique global positive solution with any positive initial value. In Sect. 3, the global dynamics of positive solutions are investigated. A whole criterion for the extinction and global asymptotic stability in the mean with probability one is established. Furthermore, the criterion for the global asymptotic stability in the probability distribution is also established. In Sect. 4, the effects of harvesting for the extinction and persistence of species are discussed, and the sufficient conditions for the existence and non-existence of optimal harvesting are obtained. We also offer the numerical examples to illustrate our main results in Sect. 5. Lastly, in Sect. 6 we give a brief conclusion and propose some interesting open problems.

2 Preliminaries

Firstly, for convenience of the statements, we denote $b_{1}=r_{1}-h _{1}-\frac{1}{2}\sigma _{1}^{2}$, $b_{2}=r_{2}+h_{2}+\frac{1}{2}\sigma _{2}^{2}$, $b_{3}=r_{3}+h_{3}+\frac{1}{2}\sigma _{3}^{2}$, $\Delta _{11}=b _{1}$, $\Delta _{21}=b_{1}a_{22}+b_{2}a_{12}$, $\Delta _{22}=b_{1}a_{21}-b _{2}a_{11}$, $\Delta _{31}={b_{1}(a_{22}a_{33}+a_{32}a_{23}) +b_{2}a _{33}a_{12}-b_{3}a_{12}a_{23}}$, $\Delta _{32}=a_{33}(b_{1}a_{21}-b_{2}a _{11})+b_{3}a_{11}a_{23}$, $\Delta _{33}=(b_{1}a_{21}-b_{2}a_{11})a _{32}-b_{3}(a_{11}a_{22}+a_{12}a_{21})$, $H_{1}=a_{11}$, $H_{2}=a_{11}a _{22}+a_{12}a_{21}$, and $H_{3}=a_{11}a_{22}a_{33}+a_{33}a_{12}a_{21}+a _{11}a_{32}a_{23}$. Obviously, when $b_{1}\geq 0$, we have $\Delta _{21}\geq 0$. Furthermore, we have the following.

Lemma 1

If $\Delta _{33}>0$, then $\Delta _{31}>0$ and $\Delta _{32}>0$.

Proof

Let $x_{1}^{*}=\frac{\Delta _{31}}{H_{3}}$, $x_{2}^{*}=\frac{\Delta _{32}}{H_{3}}$, and $x_{3}^{*}=\frac{\Delta _{33}}{H_{3}}$. Then $x_{3}^{*}>0$. By calculating, we can obtain

$$ a_{32}x_{2}^{*}=b_{3}+a_{33}x_{3}^{*}>0, \qquad a_{21}x_{1}^{*}=b_{2}+a_{22}x _{2}^{*}+a_{23}x_{3}^{*}>0. $$

Therefore, we have $\Delta _{31}>0$ and $\Delta _{32}>0$. This completes the proof. □

Lemma 2

For any real numbers $A\geq 0$, $B\geq 0$, $A_{i}\geq 0$ ($1\leq i \leq n$), and $p>0$, $q>0$ with $\frac{1}{p}+\frac{1}{q}=1$, one has

$$ \Biggl(\sum_{i=1}^{n}A_{i} \Biggr)^{p}\leq n^{p}\sum_{i=1}^{n}A_{i}^{p}, \qquad AB \leq \frac{A^{p}}{p}+\frac{B^{q}}{q}. $$

Let $\gamma =\max \{\tau _{12},\tau _{21},\tau _{23},\tau _{32}\}$. The initial condition for model (1) is given by

$$ x_{1}(\theta )=\xi (\theta ),\qquad x_{2}( \theta )=\eta (\theta ),\qquad x_{3}( \theta )=\varsigma (\theta ),\quad -\gamma \leq \theta \leq 0. $$

(2)

On the existence and the ultimate boundedness of the global positive solution for model (1), we have the following results.

Lemma 3

For any $(\xi (\theta ),\eta (\theta ),\varsigma (\theta ))\in C([- \gamma ,0],R_{+}^{3}))$, model (1) with condition (2) has a unique global solution $x(t)=(x_{1}(t),x_{2}(t),x_{3}(t))\in R ^{3}_{+}$ a.s. for all $t\geq 0$. Moreover, for any $p>0$, there exist constants $K_{1}(p)>0$, $K_{2}(p)>0$, and $K_{3}(p)>0$ such that

$$ \limsup_{t\to \infty }E\bigl[x_{1}^{p}(t)\bigr] \leq K_{1}(p),\qquad \limsup_{t\to \infty }E \bigl[x_{2}^{p}(t)\bigr]\leq K_{2}(p),\qquad \limsup _{t\to \infty }E\bigl[x_{3}^{p}(t)\bigr]\leq K_{3}(p). $$

Proof

Since the coefficients of model (1) are locally Lipschitz, from [14, 20] we obtain that, for any initial data $(\xi (\theta ),\eta ( \theta ),\varsigma (\theta ))\in C([-\gamma ,0],R_{+}^{3}))$, model (1) has a unique solution $x(t)=(x_{1}(t),x_{2}(t),x_{3}(t)) \in R^{3}_{+}$ for all $t\in [-\gamma ,\tau _{e})$, where $\tau _{e}$ is the explosion time. We need to prove $\tau _{e}=\infty $ a.s. Let $k_{0}>0$ be an enough large integer such that $\xi (0),\eta (0), \varsigma (0)\in (\frac{1}{k_{0}},k_{0})$. For each integer $k>k_{0}$, define stopping times as follows:

$$ \tau _{k}=\inf \biggl\{ t\in [0,\tau _{e}): x_{1}(t)\notin \biggl(\frac{1}{k},k\biggr),x _{2}(t) \notin \biggl(\frac{1}{k},k\biggr),x_{3}(t)\notin \biggl( \frac{1}{k},k\biggr)\biggr\} . $$

(3)

It is clear that $\tau _{k}$ is increasing with k. Set $\tau _{\infty }=\lim_{k\to \infty }\tau _{k}$. We have $\tau _{\infty }\leq \tau _{e}$ a.s. Thus, we only need to prove $\tau _{\infty }=\infty$ a.s.

If the conclusion is false, then there exist $T>0$ and $\varepsilon \in (0,1)$ such that $P(\tau _{\infty }\leq T)>\varepsilon $. Hence, there exists an integer $k_{1}>k_{0}$ such that, for any $k>k_{1}$,

$$ P(\tau _{k}\leq T)>\varepsilon . $$

(4)

Define $V_{i}(x_{i})=x_{i}-1-\ln x_{i}$ ($i=1,2,3$). Using Itô’s formula, we obtain

$$\begin{aligned}& \mathrm{d}V_{1}(x_{1})=\mathcal{L} \bigl[V_{1}(x_{1})\bigr]\,\mathrm{d}t+\sigma _{1}(x _{1}-1)\,\mathrm{d}B_{1}(t), \\& \mathrm{d}V_{2}(x_{2})=\mathcal{L}\bigl[V_{2}(x _{2})\bigr]\,\mathrm{d}t+\sigma _{2}(x_{2}-1) \,\mathrm{d}B_{2}(t), \\& \mathrm{d}V_{3}(x _{3})=\mathcal{L}\bigl[V_{3}(x_{3}) \bigr]\,\mathrm{d}t+\sigma _{3}(x_{3}-1)\,\mathrm{d}B _{3}(t), \end{aligned}$$

(5)

where

$$\begin{aligned}& \begin{aligned} &\mathcal{L}\bigl[V_{1}(x_{1}) \bigr]= (x_{1}-1) \biggl(r_{1}-h_{1}-a_{11}x_{1}(t)-a_{12} \int _{-\tau _{12}}^{0}x_{2}(t+\theta )\,\mathrm{d}\mu _{12}(\theta )\biggr) + \frac{1}{2}\sigma _{1}^{2}, \\ &\mathcal{L}\bigl[V_{2}(x_{2})\bigr]=(x_{2}-1) \biggl(-r _{2}-h_{2}+a_{21} \int _{-\tau _{21}}^{0}x_{1}(t+\theta )\,\mathrm{d}\mu _{12}( \theta )-a_{22}x_{2}(t) \\ &\hphantom{\mathcal{L}[V_{2}(x_{2})]=}{}-a_{23} \int _{-\tau _{23}}^{0}x_{3}(t+\theta )\,\mathrm{d}\mu _{23}(\theta )\biggr)+\frac{1}{2}\sigma _{2}^{2}, \\ &\mathcal{L}\bigl[V _{3}(x_{3})\bigr]=(x_{3}-1) \biggl(-r_{3}-h_{3}-a_{33}x_{3}(t)+a_{32} \int _{-\tau _{32}}^{0}x_{2}(t+\theta )\,\mathrm{d}\mu _{32}(\theta )\biggr) + \frac{1}{2}\sigma _{3}^{2}. \end{aligned} \end{aligned}$$

(6)

For any integer $n>0$, using Lemma 2 we can obtain

$$\begin{aligned}& \begin{aligned} &\mathcal{L}\bigl[V_{1}(x_{1}) \bigr]\leq \frac{\sigma _{1}^{2}}{2}-(r_{1}-h_{1})+ \frac{n ^{2}}{2}a_{12}+(r_{1}-h_{1})x_{1}+a_{11}x_{1}-a_{11}x_{1}^{2} \\ &\hphantom{\mathcal{L}[V_{1}(x_{1})]\leq}{}+\frac{1}{2n ^{2}}a_{12} \int _{-\tau _{12}}^{0}x_{2}^{2}(t+\theta )\,\mathrm{d}\mu _{12}( \theta ), \\ &\mathcal{L}\bigl[V_{2}(x_{2})\bigr]\leq \frac{\sigma _{2}^{2}}{2}+(r _{2}+h_{2}) +\frac{n}{2}a_{21} \int _{-\tau _{21}}^{0}x_{1}^{2}(t+\theta )\,\mathrm{d}\mu _{21}(\theta )-(r_{2}+h_{2})x_{2}+a_{22}x_{2} \\ &\hphantom{\mathcal{L}[V_{2}(x_{2})]\leq}{}-a_{22}x _{2}^{2}+ \frac{x_{2}^{2}}{2n}a_{21}+\frac{n^{2}}{2}a_{23}+ \frac{1}{2n ^{2}}a_{23} \int _{-\tau _{23}}^{0}x_{3}^{2}(t+\theta )\,\mathrm{d}\mu _{23}( \theta ), \\ &\mathcal{L}\bigl[V_{3}(x_{3})\bigr]\leq \frac{\sigma _{3}^{2}}{2}+(r _{3}+h_{3})+\frac{x_{3}^{2}}{2n}a_{32}-(r_{3}+h_{3})x_{3}+a_{33}x_{3}-a _{33}x_{3}^{2} \\ &\hphantom{\mathcal{L}[V_{3}(x_{3})]\leq}{}+\frac{n}{2}a_{32} \int _{-\tau _{32}}^{0}x_{2}^{2}(t+ \theta )\,\mathrm{d}\mu _{32}(\theta ). \end{aligned} \end{aligned}$$

(7)

Define $V_{0}(x_{1},x_{2},x_{3})=\alpha V_{1}(x_{1})+V_{2}(x_{2})+ \eta V_{3}(x_{3})+V_{4}(t)$, where

$$\begin{aligned} V_{4}(t) = &\frac{\alpha }{2n^{2}}a_{12} \int _{-\tau _{12}}^{0} \int _{t+\theta }^{t}x_{2}^{2}(s) \,\mathrm{d}s\,\mathrm{d}\mu _{12}(\theta ) +\biggl( \frac{n}{2}a_{21} \int _{-\tau _{21}}^{0} \int _{t+\theta }^{t}x_{1}^{2}(s) \,\mathrm{d}s\,\mathrm{d}\mu _{21}(\theta ) \\ &{}+\frac{1}{2n^{2}}a_{23} \int _{-\tau _{23}}^{0} \int _{t+\theta }^{t}x_{3}^{2}(s) \,\mathrm{d}s \,\mathrm{d}\mu _{23}(\theta )\biggr) +\eta \frac{n}{2}a_{32} \int _{-\tau _{32}} ^{0} \int _{t+\theta }^{t}x_{2}^{2}(s) \,\mathrm{d}s\,\mathrm{d}\mu _{32}(\theta ). \end{aligned}$$

Choose the positive constants α, η and integer $n>0$ such that

$$ \begin{aligned} &\biggl(-a_{22}+ \frac{1}{2n}a_{21}\biggr) +\frac{n\eta }{2}a_{32}+ \frac{\alpha }{2n ^{2}}a_{12}< 0, \\ &\biggl(-a_{33}+\frac{1}{2n}a_{32}\biggr)\eta + \frac{1}{2n^{2}}a _{23}< 0, -a_{11}\alpha + \frac{n}{2}a_{21}< 0. \end{aligned} $$

(8)

In fact, from $(-a_{33}+\frac{1}{2n}a_{32})\eta +\frac{1}{2n^{2}}a _{23}=0$ and $-a_{11}\alpha +\frac{n}{2}a_{21}=0$, we have $\eta =\frac{a _{23}}{n(2na_{33}-a_{32})}$ and $\alpha =\frac{na_{21}}{2a_{11}}$. Substituting η and α into the left of the first inequality of (8), we can obtain that there is enough large $n>0$ such that $2na_{33}-a_{32}>0$ and $-a_{22}+\frac{a_{21}}{2n}+\frac{a_{32}a_{23}}{2(2na _{33}-a_{32})}+\frac{a_{12}a_{21}}{4na_{11}}<-\frac{1}{2}a_{22}$. From this, we further choose positive constants $\eta >\frac{a_{23}}{n(2na _{33}-a_{32})}$ and $\alpha >\frac{na_{21}}{2a_{11}}$ such that (8) holds.

Using Itô’s formula, from (5) we have

$$\begin{aligned} d\bigl[V_{0}(x_{1},x_{2},x_{3}) \bigr] = &\mathcal{L}V_{0}(x_{1},x_{2},x_{3})\,\mathrm{d}t+ \alpha \sigma _{1}(x_{1}-1)\,\mathrm{d}B_{1}(t) \\ &{}+\sigma _{2}(x_{2}-1) \,\mathrm{d}B_{2}(t)+\eta \sigma _{3}(x_{3}-1)\,\mathrm{d}B_{3}(t). \end{aligned}$$

From (6) and (7), we obtain

$$\begin{aligned} \mathcal{L}\bigl[V_{0}(x_{1},x_{2},x_{3}) \bigr] = &\alpha \mathcal{L}V_{1}(x_{1})+ \mathcal{L}V_{2}(x_{2})+\eta \mathcal{L}V_{3}(x_{3})+ \frac{d}{dt}V _{4}(t) \\ \leq &\frac{\alpha \sigma _{1}^{2}}{2}-\alpha (r_{1}-h_{1})+ \frac{ \alpha n^{2}}{2}a_{12}+\alpha (r_{1}-h_{1})x_{1}+ \alpha a_{11}x_{1}- \alpha a_{11}x_{1}^{2} \\ &{}+\frac{\sigma _{2}^{2}}{2}+(r_{2}+h_{2}) -(r_{2}+h_{2})x_{2}+ a_{22}x _{2}-a_{22}x_{2}^{2}+ \frac{x_{2}^{2}}{2n}a_{21} \\ &{}+\frac{n^{2}}{2}a _{23}+\frac{\eta \sigma _{3}^{2}}{2}+(r_{3}+h_{3}) \eta +\frac{\eta x _{3}^{2}}{2n}a_{32}-\eta (r_{3}+h_{3})x_{3}+ \eta a_{33}x_{3} \\ &{}- \eta a_{33}x_{3}^{2}+\frac{\alpha }{2n^{2}}x_{2}^{2}a_{12} + \frac{n}{2}x_{1}^{2}a_{21}+ \frac{1}{2n^{2}}x_{3}^{2}a_{23} + \frac{n \eta }{2}x_{2}^{2}a_{32}. \end{aligned}$$

From (8) we can obtain that there exists a constant $K>0$ such that

$$\begin{aligned} d\bigl[V_{0}(x_{1},x_{2},x_{3}) \bigr] \leq & K\,\mathrm{d}t+\alpha \sigma _{1}(x_{1}-1) \,\mathrm{d}B_{1}(t) \\ &{}+\sigma _{2}(x_{2}-1)\,\mathrm{d}B_{2}(t)+\eta \sigma _{3}(x_{3}-1)\,\mathrm{d}B_{3}(t). \end{aligned}$$

(9)

Then, from (4) and (9), a similar argument as in [21] we can get the following contradiction:

$$ \infty >V_{0}\bigl(x_{1}(0),x_{2}(0),x_{3}(0) \bigr)+KT\geq \infty . $$

Thus, we obtain $\tau _{\infty }=\infty$ a.s., and hence, $\tau _{e}= \infty$ a.s.

For any $p>0$, let $Q_{1}(t)=e^{t}x_{1}^{p}(t)$. By Itô’s formula, we have

$$ dQ_{1}(t)=\mathcal{L}Q_{1}(t)\,\mathrm{d}t+pe^{t}x_{1}^{p} \sigma _{1}\,\mathrm{d}B _{1}(t), $$

(10)

where

$$\begin{aligned} \mathcal{L}Q_{1}(t) =&e^{t}x_{1}^{p} \biggl\{ 1+\frac{p(p-1)\sigma _{1}^{2}}{2}+p\biggl[r _{1}-h_{1}-a_{11}x_{1} -a_{12} \int _{-\tau _{12}}^{0}x_{2}(t+\theta ) \,\mathrm{d}\mu _{12}(\theta )\biggr]\biggr\} \\ \leq& K_{1}(p)e^{t} \end{aligned}$$

(11)

with

$$ K_{1}(p)=\max_{x_{1}\geq 0}\biggl\{ \biggl[p(r_{1}-h_{1})+1+ \frac{p(p-1)\sigma _{1} ^{2}}{2}\biggr]x_{1}^{p}-pa_{11}x_{1}^{p+1} \biggr\} . $$

Integrating both sides of (10) and then taking expectations lead to

$$ E\bigl[e^{t}x_{1}^{p}\bigr]-\xi ^{p}(0)\leq K_{1}(p) \bigl(e^{t}_{1}-1 \bigr), $$

(12)

which implies $\limsup_{t\to \infty }E[x_{1}^{p}(t)]\leq K_{1}(p)$.

For any constant $p>0$ and integer $n>0$ with $a_{22}-a_{21} \frac{p}{p+1}n^{-\frac{p+1}{p}}>0$, we define $Q_{2}(t)$ as follows:

$$ Q_{2}(t)=C_{1}^{*}Q_{1}(t)+e^{t}x_{2}^{p}(t) +e^{\tau _{21}}\frac{pn ^{p+1}}{p+1}a_{21} \int _{-\tau _{21}}^{0} \int _{t+\theta }^{t}e^{s}x_{1} ^{p+1}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{21}(\theta ), $$

(13)

where $C_{1}^{*}=a_{11}^{-1}e^{\tau _{21}}n^{p+1}a_{21}$. We have by Itô’s formula

$$ dQ_{2}(t)=\mathcal{L}Q_{2}(t)\,\mathrm{d}t+C_{1}^{*}pe^{t}x_{1}^{p} \sigma _{1} \,\mathrm{d}B_{1}(t)+pe^{t}x_{2}^{p} \sigma _{2}\,\mathrm{d}B_{2}(t). $$

(14)

From (11), we have

$$\begin{aligned} \mathcal{L}Q_{2}(t) = &C^{*}_{1} \mathcal{L}Q_{1}(t)+\mathcal{L}\bigl(e^{t}x _{2}^{p}(t)\bigr)+\frac{d}{dt}\biggl(e^{\tau _{21}} \frac{pn^{p+1}}{p+1}a_{21} \int _{-\tau _{21}}^{0} \int _{t+\theta }^{t}e^{s}x_{1}^{p+1}(s) \,\mathrm{d}s \,\mathrm{d}\mu _{21}(\theta )\biggr) \\ =&C^{*}_{1}e^{t}x_{1}^{p} \biggl\{ 1+\frac{p(p-1) \sigma _{1}^{2}}{2}+p\biggl[r_{1}-h_{1}-a_{11}x_{1} -a_{12} \int _{-\tau _{12}} ^{0}x_{2}(t+\theta )\,\mathrm{d}\mu _{12}(\theta )\biggr]\biggr\} \\ &{}+e^{t}x_{2}^{p}\biggl\{ 1+\frac{p(p-1) \sigma _{2}^{2}}{2}+p \biggl[-r_{2}-h_{2}+a_{21} \int _{-\tau _{21}}^{0}x_{1}(t+ \theta )\,\mathrm{d}\mu _{21}(\theta ) \\ &{}-a_{22}x_{2}(t)-a_{23} \int _{-\tau _{23}}^{0}x_{3}(t+\theta )\,\mathrm{d}\mu _{23}(\theta )\biggr]\biggr\} \\ &{}+e ^{\tau _{21}}\frac{pn^{p+1}}{p+1}a_{21}\biggl(e^{t}x_{1}^{p+1}(t)- \int _{-\tau _{21}}^{0}e^{t+\theta }x_{1}^{p+1}(t+ \theta )\,\mathrm{d}\mu _{21}(\theta )\biggr) \\ \leq &C_{1}^{*}e^{t}\biggl\{ \biggl[1+ \frac{p(p-1)\sigma _{1}^{2}}{2}+p(r_{1}-h_{1})\biggr]x_{1}^{p}-pa_{11}x_{1} ^{p+1}\biggr\} \\ &{}+e^{t}\biggl\{ \biggl[1+\frac{p(p-1)\sigma _{2}^{2}}{2}-p(r_{2}+h_{2}) \biggr]x _{2}^{p}-p\biggl[a_{22}-a_{21} \frac{p}{p+1}n^{-\frac{{p+1}}{p}}\biggr]x_{2}^{p+1} \\ &{}+\frac{p}{p+1}n^{p+1}a_{21} \int _{-\tau _{21}}^{0}x_{1}^{p+1}(t+ \theta )\,\mathrm{d}\mu _{21}(\theta )\biggr\} \\ &{}+e^{\tau _{21}} \frac{pn^{p+1}}{p+1}a_{21}\biggl(e^{t}x_{1}^{p+1}(t) -e^{-\tau _{21}} \int _{-\tau _{21}}^{0}e^{t}x_{1}^{p+1}(t+ \theta )\,\mathrm{d}\mu _{21}( \theta )\biggr) \\ \leq &e^{t}\biggl\{ \biggl[1+\frac{p(p-1)\sigma _{2}^{2}}{2}-p(r_{2}+h _{2})\biggr]x_{2}^{p}-p\biggl[a_{22}-a_{21} \frac{p}{p+1}n^{-\frac{{p+1}}{p}}\biggr]x _{2}^{p+1} \\ &{}+C_{1}^{*}\biggl[1+\frac{p(p-1)\sigma _{1}^{2}}{2}+p(r_{1}-h _{1})\biggr]x_{1}^{p}-e^{\tau _{21}} \frac{p^{2}}{p+1}n^{p+1}a_{21}x_{1}^{p+1} \biggr\} . \end{aligned}$$

(15)

Obviously, there is a constant $K_{2}(p)>0$ such that $\mathcal{L}Q _{2}(t)\leq K_{2}(p)e^{t}$. According to (13) and (14), we obtain

$$ E\bigl[e^{t}x_{2}^{p}\bigr]\leq EQ_{2}(t)\leq EQ_{2}(0)+K_{2}(p) \bigl(e^{t}-1\bigr), $$

which implies $\limsup_{t\to \infty }E[x_{2}^{p}(t)]\leq K_{2}(p)$.

For any constant $p>0$ and integer $n>0$ with $a_{33}-a_{32} \frac{p}{p+1}n^{-\frac{p+1}{p}}>0$, we define $Q_{3}(t)$ as follows:

$$ Q_{3}(t)=C_{2}^{*}Q_{2}(t)+e^{t}x_{3}^{p} +e^{\tau _{32}} \frac{pn^{p+1}}{p+1}a_{32} \int _{-\tau _{32}}^{0} \int _{t+\theta }^{t}e ^{s}x_{2}^{p+1}(s) \,\mathrm{d}s\,\mathrm{d}\mu _{32}(\theta ), $$

(16)

where $C_{2}^{*}=a_{22}^{-1}e^{\tau _{32}}n^{p+1}a_{32}$.

Applying Itô’s formula to $Q_{3}(t)$, we obtain

$$ dQ_{3}(t)=\mathcal{L}Q_{3}(t)\,\mathrm{d}t+C_{2}^{*} \bigl(C_{1}^{*}pe^{t}x_{1}^{p} \sigma _{1}\,\mathrm{d}B_{1}(t)+pe^{t}x_{2}^{p} \sigma _{2}\,\mathrm{d}B_{2}(t)\bigr)+pe ^{t}x_{3}^{p} \sigma _{3}\,\mathrm{d}B_{3}(t), $$

(17)

where

$$\begin{aligned} \mathcal{L}Q_{3}(t) = &C_{2}^{*} \mathcal{L}Q_{2}(t)+\mathcal{L}\bigl[e^{t}x _{3}^{p}\bigr]+a_{32}e^{\tau _{32}}e^{t}x_{2}^{p+1} \frac{pn^{p+1}}{p+1} \\ &{}-a _{32}e^{\tau _{32}}\frac{pn^{p+1}}{p+1} \int _{-\tau _{32}}^{0}e^{t}x_{2} ^{p+1}(t+\theta )\,\mathrm{d}\mu _{32}(\theta ) \\ \leq & C_{2}^{*}\mathcal{L}Q _{2}(t)+\mathcal{L} \bigl[e^{t}x_{3}^{p}\bigr]+a_{32}e^{\tau _{32}}e^{t}x_{2}^{p+1} \frac{pn ^{p+1}}{p+1} \\ &{}-a_{32}\frac{pn^{p+1}}{p+1} \int _{-\tau _{32}}^{0}x_{2}^{p+1}(t+ \theta )\,\mathrm{d}\mu _{32}(\theta ). \end{aligned}$$

Since

$$\begin{aligned} \mathcal{L}\bigl[e^{t}x_{3}^{p} \bigr] = &e^{t}\biggl\{ \biggl[1+\frac{p(p-1)\sigma _{3}^{2}}{2}+p(-r _{3}-h_{3})\biggr]x_{3}^{p} \\ &{}+a_{32}px_{3}^{p} \int _{-\tau _{32}}^{0}x_{2}(t+ \theta )\,\mathrm{d}\mu _{32}(\theta )-a_{33}px_{3}^{p+1}(t)\biggr\} \\ \leq & e ^{t}\biggl\{ \biggl[1-p(r_{3}+h_{3})+ \frac{p(p-1)\sigma _{3}^{2}}{2}\biggr]x_{3}^{p}+a _{32} \frac{p}{p+1}n^{p+1} \int _{-\tau _{32}}^{0}x_{2}^{p+1}(t+\theta ) \,\mathrm{d}\mu _{32}(\theta ) \\ &{}-p\biggl[a_{33}-a_{32}\frac{p}{p+1}n^{- \frac{p+1}{p}} \biggr]x_{3}^{p+1}\biggr\} , \end{aligned}$$

from (15) we further obtain

$$\begin{aligned} \mathcal{L}Q_{3}(t) \leq & e^{t}\biggl\{ \biggl[1-p(r_{3}+h_{3})+\frac{p(p-1)\sigma _{3}^{2}}{2} \biggr]x_{3}^{p}-p\biggl[a_{33} -a_{32} \frac{p}{p+1}n^{- \frac{{p+1}}{p}}\biggr]x_{3}^{p+1} \\ &{}+\biggl(1-p(r_{2}+h_{2})+\frac{p(p-1)\sigma _{2}^{2}}{2} \biggr)x_{2}^{p}C_{2}^{*} \\ &{}- \frac{p^{2}}{p+1}\bigl(n^{p+1}a_{32}e^{ \tau _{32}}+n^{-\frac{p+1}{p}}a_{21}C_{2}^{*} \bigr)x_{2}^{p+1} \\ &{}-C_{2} ^{*}e^{\tau _{21}}\frac{p^{2}}{p+1}n^{p+1}a_{21}x_{1}^{p+1}+C_{1}^{*}C _{2}^{*}\biggl[1+p(r_{1}-h_{1})+ \frac{p(p-1)\sigma _{1}^{2}}{2}\biggr]x_{1}^{p}\biggr\} . \end{aligned}$$

Obviously, there is a constant $K_{3}(p)>0$ such that $\mathcal{L}Q _{3}(t)\leq K_{3}(p)e^{t}$. Hence, from (16) and (17) we obtain

$$ E\bigl[e^{t}x_{3}^{p}\bigr]\leq E \bigl[Q_{3}(t)\bigr]\leq E\bigl[Q_{3}(0)\bigr]+K_{3}(p) \bigl(e^{t}-1\bigr). $$

Consequently, $\limsup_{t\to \infty }E[x_{3}^{p}(t)]\leq K_{3}(p)$. This completes the proof. □

Lemma 4

Assume that functions $Y\in C(R_{+}\times \varOmega , R_{+})$ and $Z\in C(R_{+}\times \varOmega , R)$ satisfy $\lim_{t\rightarrow \infty } \frac{Z(t)}{t}=0$ a.s.

(1)
If there are three positive constants T, β, and $\beta _{0}$ such that, for all $t\geq T$,
$$ \ln Y(t)=\beta t-\beta _{0} \int _{0}^{t}Y(s)\,\mathrm{d}s+Z(t)\quad \textit{a.s.}, $$
then $\lim_{t\to \infty }\langle Y(t)\rangle = \frac{\beta }{\beta _{0}}$ a.s., and $\lim_{t\to \infty }\frac{ \ln Y(t)}{t}=0$ a.s.
(2)
If there exist two positive constants $\beta _{0}$ and T, and a constant $\beta \in R$ such that, for $t\geq T$,
$$ \ln Y(t)\leq \beta t-\beta _{0} \int _{0}^{t}Y(s)\,\mathrm{d}s+Z(t)\quad \textit{a.s.}, $$
then $\limsup_{t\to \infty }\langle Y(t)\rangle \leq \frac{\beta }{ \beta _{0}}$ a.s. if $\beta \geq 0$, and $\lim_{t\to \infty }Y(t)=0 $ a.s. if $\beta < 0$.
(3)
If there exist three positive constants T, β, and $\beta _{0}$ such that, for all $t\geq T$,
$$ \ln Y(t)\geq \beta t-\beta _{0} \int _{0}^{t}Y(s)\,\mathrm{d}s+Z(t)\quad \textit{a.s.}, $$
then $\liminf_{t\to \infty }\langle Y(t)\rangle \geq \frac{\beta }{ \beta _{0}}$ a.s.

Lemma 4 can be found in [22]. We consider the following auxiliary system:

$$ \textstyle\begin{cases} \mathrm{d}Y_{1}(t)= Y_{1}(t)[r_{1}-h_{1}-a_{11}Y_{1}(t)]\,\mathrm{d}t+\sigma _{1}Y_{1}(t)\,\mathrm{d}B_{1}(t),\\ \mathrm{d}Y_{2}(t)=Y_{2}(t)[-r_{2}-h _{2}+a_{21}\int _{-\tau _{21}}^{0}Y_{1}(t+\theta )\,\mathrm{d}\mu _{21}( \theta ) -a_{22}Y_{2}(t)]\,\mathrm{d}t \\ \hphantom{\mathrm{d}Y_{2}(t)=}{}+\sigma _{2}Y_{2}(t)\,\mathrm{d}B_{2}(t), \\ \mathrm{d}Y_{3}(t)=Y_{3}(t)[-r_{3}-h_{3}+a_{32}\int _{-\tau _{32}} ^{0}Y_{2}(t+\theta )\,\mathrm{d}\mu _{32}(\theta ) -a_{33}Y_{3}(t)] \,\mathrm{d}t \\ \hphantom{\mathrm{d}Y_{3}(t)=}{}+\sigma _{3}Y_{3}(t)\,\mathrm{d}B_{3}(t) \end{cases} $$

(18)

with the initial condition

$$ Y_{1}(\theta )=\xi (\theta ),\qquad Y_{2}( \theta )=\eta (\theta ), \qquad Y_{3}( \theta )=\zeta (\theta ),\quad -r \leq \theta \leq 0. $$

(19)

Firstly, by a similar argument as in the proof of Lemma 3, we can obtain that for any condition (19) system (18) has a unique global solution $(Y_{1}(t),Y_{2}(t),Y_{3}(t))\in R^{3}_{+}$ a.s. for all $t\geq 0$. We have the following results.

Lemma 5

Assume that $(Y_{1}(t),Y_{2}(t),Y_{3}(t))$ is a global positive solution of system (18). Then we have:

(1)
If $\Delta _{11}<0$, then $\lim_{t\to \infty }Y_{i}(t)=0$ a.s. for $i=1,2,3$.
(2)
If $\Delta _{11}=0$, then $\lim_{t\to \infty }\langle Y_{1}(t) \rangle =0$ and $\lim_{t\to \infty }Y_{i}(t)=0$ a.s. for $i=2,3$.
(3)
If $\Delta _{11}>0$ and $\Delta _{22}<0$, then $\lim_{t\to \infty }\langle Y_{1}(t)\rangle =\frac{\Delta _{11}}{a_{11}}$ and $\lim_{t\to \infty }Y_{i}(t)=0$ a.s. for $i=2,3$.
(4)
If $\Delta _{22}=0$, then $\lim_{t\to \infty }\langle Y_{1}(t) \rangle =\frac{\Delta _{11}}{a_{11}}$, $\lim_{t\to \infty }\langle Y _{2}(t)\rangle =0 $, and $\lim_{t\to \infty }Y_{3}(t)=0$ a.s.
(5)
If $\Delta _{22}>0$ and $\Delta _{33}<0$, then $\lim_{t\to \infty }\langle Y_{1}(t)\rangle =\frac{\Delta _{11}}{a_{11}}$, $\lim_{t\to \infty }\langle Y_{2}(t)\rangle =\frac{\Delta _{22}}{a_{11}a _{22}}$, and $\lim_{t\to \infty }Y_{3}(t) =0$ a.s.
(6)
If $\Delta _{33}=0$, then $\lim_{t\to \infty }\langle Y_{1}(t) \rangle =\frac{\Delta _{11}}{a_{11}}$, $\lim_{t\to \infty }\langle Y _{2}(t)\rangle =\frac{\Delta _{22}}{a_{11}a_{22}}$, and $\lim_{t\to \infty }\langle Y_{3}(t)\rangle =0$ a.s.
(7)
If $\Delta _{33}>0$, then
$$ \lim_{t\to \infty }\bigl\langle Y_{1}(t)\bigr\rangle = \frac{\Delta _{11}}{a_{11}},\qquad \lim_{t\to \infty }\bigl\langle Y_{2}(t) \bigr\rangle =\frac{\Delta _{22}}{a_{11}a_{22}},\qquad \lim _{t\to \infty } \bigl\langle Y_{3}(t)\bigr\rangle = \frac{\Delta _{33}}{a_{11}a_{22}a_{33}} \quad \textit{a.s.} $$
(8)
$\limsup_{t\to \infty }\frac{\ln Y_{i}(t)}{t}\leq 0$ a.s. for $i=1,2,3$.

Proof

Applying Itô’s formula to system (18), we have

$$\begin{aligned}& \ln Y_{1}(t)=b_{1}t-a_{11} \int _{0}^{t}Y_{1}(s)\,\mathrm{d}s+\sigma _{1}B _{1}(t)+\ln Y_{1}(0), \end{aligned}$$

(20)

$$\begin{aligned}& \ln Y_{2}(t)= -b_{2}t+a_{21} \int _{0}^{t} \int _{-\tau _{21}}^{0}Y_{1}(s+ \theta )\,\mathrm{d}\mu _{21}(\theta )\,\mathrm{d}s \\& \hphantom{\ln Y_{2}(t)=}{} -a_{22} \int _{0}^{t}Y_{2}(s) \,\mathrm{d}s+\sigma _{2}B_{2}(t)+\ln Y_{2}(0) \\& \hphantom{\ln Y_{2}(t)}=-b_{2}t+a_{21} \int _{0} ^{t}Y_{1}(s)\,\mathrm{d}s -a_{22} \int _{0}^{t}Y_{2}(s)\,\mathrm{d}s+\psi _{1}(t), \end{aligned}$$

(21)

and

$$\begin{aligned} \ln Y_{3}(t) = &-b_{3}t+a_{32} \int _{0}^{t} \int _{-\tau _{32}}^{0}Y_{2}(s+ \theta )\,\mathrm{d}\mu _{32}(\theta )\,\mathrm{d}s \\ &{} -a_{33} \int _{0}^{t}Y_{3}(s) \,\mathrm{d}s+\sigma _{3}B_{3}(t)+\ln Y_{3}(0) \\ =&-b_{3}t+a_{32} \int _{0} ^{t}Y_{2}(s)\,\mathrm{d}s -a_{33} \int _{0}^{t}Y_{3}(s)\,\mathrm{d}s+\psi _{2}(t), \end{aligned}$$

(22)

where

$$\begin{aligned}& \psi _{1}(t)= \sigma _{2}B_{2}(t)+\ln Y_{2}(0)+a_{21} \int _{-\tau _{21}} ^{0} \int _{\theta }^{0}Y_{1}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{21}(\theta ) \\& \hphantom{\psi _{1}(t)=}{} -a _{21} \int _{-\tau _{21}}^{0} \int _{t+\theta }^{t}Y_{1}(s)\,\mathrm{d}s \,\mathrm{d} \mu _{21}(\theta ), \\& \psi _{2}(t)=\sigma _{3}B_{3}(t)+\ln Y _{3}(0)+a_{32} \int _{-\tau _{32}}^{0} \int _{\theta }^{0}Y_{2}(s)\,\mathrm{d}s \,\mathrm{d}\mu _{32}(\theta ) \\& \hphantom{\psi _{2}(t)=}{} -a_{32} \int _{-\tau _{32}}^{0} \int _{t+\theta }^{t}Y_{2}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{32}(\theta ). \end{aligned}$$

Assume $\Delta _{11}\leq 0$. From Lemma 4 and (20) we have $\lim_{t\to \infty }Y_{1}(t)=0$ a.s. or $\lim_{t\to \infty }\langle Y_{1}(t)\rangle =0$ a.s. Thus, $\lim_{t\to \infty }\frac{1}{t}\psi _{1}(t)=0$ a.s. From (21), we have $\lim_{t\to \infty }Y_{2}(t)=0$, then $\lim_{t\to \infty }\frac{1}{t} \psi _{2}(t)=0$ a.s. From (22), we further have $\lim_{t\to \infty }Y_{3}(t) =0$ a.s.

Assume $\Delta _{11}>0$ and $\Delta _{22}<0$. From Lemma 4 and (20) we obtain $\lim_{t\to \infty }\langle Y_{1}(t)\rangle =\frac{ \Delta _{11}}{a_{11}}$ a.s. Thus, $\int _{0}^{t}Y_{1}(s)\,\mathrm{d}s=\frac{ \Delta _{11}}{a_{11}}t+\alpha _{1}(t)$ for any $t\geq 0$, where $\lim_{t\to \infty }\frac{\alpha _{1}(t)}{t}=0$ a.s. From (21), we obtain

$$ \ln Y_{2}(t) =\frac{\Delta _{22}}{a_{11}}t -a_{22} \int _{0}^{t}Y_{2}(s) \,\mathrm{d}s+\psi _{1}(t)+a_{21}\alpha _{1}(t). $$

(23)

Since $\lim_{t\to \infty }\frac{1}{t}\psi _{1}(t)=0$ a.s., from Lemma 4 we obtain $\lim_{t\to \infty }Y_{2}(t)=0$ a.s. Further, we also have $\lim_{t\to \infty }Y_{3}(t)=0$ a.s.

Assume $\Delta _{22}=0$. Then we have $\Delta _{11}>0$. By a similar argument we obtain $\lim_{t\to \infty }\langle Y_{1}(t)\rangle =\frac{ \Delta _{11}}{a_{11}}$ a.s., $\lim_{t\to \infty }\langle Y_{2}(t) \rangle =0$ a.s., and $\lim_{t\to \infty }Y_{3}(t)=0$ a.s.

Assume $\Delta _{22}>0$ and $\Delta _{33}<0$. Then we have $\Delta _{11}>0$. From Lemma 4, (20), and (23) we directly obtain $\lim_{t\to \infty }\langle Y_{1}(t)\rangle =\frac{ \Delta _{11}}{a_{11}}$ a.s. and $\lim_{t\to \infty }\langle Y_{2}(t) \rangle =\frac{\Delta _{22}}{a_{11}a_{22}}$ a.s. Hence, $\int _{0}^{t}Y _{2}(s)\,\mathrm{d}s=\frac{\Delta _{22}}{a_{11}a_{22}}t+\alpha _{2}(t)$ for any $t\geq 0$, where $\lim_{t\to \infty }\frac{\alpha _{2}(t)}{t}=0$ a.s. From (22), we obtain

$$ \begin{aligned} \ln Y_{3}(t) = & \frac{\Delta _{33}}{a_{11}a_{22}}t -a_{33} \int _{0}^{t}Y _{3}(s)\,\mathrm{d}s+\psi _{2}(t)+a_{32}\alpha _{2}(t). \end{aligned} $$

(24)

Since $\lim_{t\to \infty }\frac{1}{t}\psi _{2}(t)=0$ a.s., from Lemma 4 we obtain $\lim_{t\to \infty }Y_{3}(t)=0$ a.s.

Assume $\Delta _{33}=0$ or $\Delta _{33}>0$. Then we have $\Delta _{11}>0$ and $\Delta _{22}>0$. Hence, we obtain $\lim_{t\to \infty }\langle Y _{1}(t)\rangle =\frac{\Delta _{11}}{a_{11}}$ and $\lim_{t\to \infty } \langle Y_{2}(t)\rangle =\frac{\Delta _{22}}{a_{11}a_{22}}$ a.s. Then, from (24) and Lemma 4 we further obtain $\lim_{t\to \infty } \langle Y_{3}(t)\rangle =0$ a.s. or $\lim_{t\to \infty }\langle Y _{3}(t)\rangle =\frac{\Delta _{33}}{a_{11}a_{22}a_{33}}$ a.s.

For any $i\in \{1,2,3\}$, from the above discussions we obtain that there is one of the following three cases: (a) $\lim_{t\to \infty }Y _{i}(t)=0$ a.s., (b) $\lim_{t\to \infty }\langle Y_{i}(t)\rangle =0 $ a.s., (c) $\lim_{t\to \infty }\langle Y_{i}(t)\rangle =\alpha _{i}$ a.s., where $\alpha _{1}=\frac{\Delta _{11}}{a_{11}}$, $\alpha _{2}=\frac{\Delta _{22}}{a_{11}a_{22}}$, and $\alpha _{3}=\frac{ \Delta _{33}}{a_{11}a_{22}a_{33}}$. For cases (a) and (b), we directly have $\limsup_{t\to \infty }\frac{\ln Y_{i}(t)}{t}\leq 0$ a.s. For case (c), from (20) or (23), or (24) we can obtain $\limsup_{t\to \infty }\frac{\ln Y_{i}(t)}{t}= 0$ a.s. Therefore, conclusion (8) holds. This completes the proof. □

Lemma 6

Assume that $(x_{1}(t),x_{2}(t),x_{3}(t))$ and $(Y_{1}(t),Y_{2}(t),Y _{3}(t))$ are the solutions of model (1) and system (18), respectively. If the initial values satisfy $x_{i}( \theta )\leq Y_{i}(\theta )$ for all $-r\leq \theta \leq 0$ and $i=1,2,3$, then

(1)
$x_{i}(t)\leq Y_{i}(t)$ for all $t\geq 0$, $i=1,2,3$,
(2)
$\limsup_{t\to \infty }\frac{\ln x_{i}(t)}{t}\leq 0$ a.s., $i=1,2,3$,
(3)
for any constant $\tau >0$, $\lim_{t\to \infty }\frac{1}{t} \int _{t-\tau }^{t}x_{i}(s)\,\mathrm{d}s=0$ a.s., $i=1,2,3$.

Proof

From model (1) we obtain

$$\begin{aligned}& \mathrm{d}x_{1}(t)\leq x_{1}(t) \bigl[r_{1}-h_{1}-a_{11}x_{1}(t)\bigr] \,\mathrm{d}t+\sigma _{1}x_{1}(t) \,\mathrm{d}B_{1}(t), \\& \mathrm{d}x_{2}(t)\leq x_{2}(t)\biggl[-r_{2}-h_{2}+a_{21} \int _{-\tau _{21}}^{0}x_{1}(t+\theta ) \,\mathrm{d}\mu _{21}(\theta )-a_{22}x_{2}(t)\biggr]\,\mathrm{d}t+ \sigma _{2}x_{2}(t) \,\mathrm{d}B_{2}(t), \\& \mathrm{d}x_{3}(t)= x_{3}(t)\biggl[-r_{3}-h_{3}+a_{32} \int _{-\tau _{32}}^{0}x_{2}(t+\theta ) \,\mathrm{d}\mu _{32}(\theta )-a_{33}x_{3}(t)\biggr]\,\mathrm{d}t+ \sigma _{3}x_{3}(t) \,\mathrm{d}B_{3}(t). \end{aligned}$$

Using the comparison theorem and Theorem 2.1 given in Bao and Yuan [23], for any $t\geq 0$, we obtain $x_{i}(t)\leq Y_{i}(t)$ ($i=1,2,3$). Then from Lemma 5 we obtain that $\limsup_{t\to \infty } \frac{\ln x_{i}(t)}{t}\leq 0$ a.s. ($i=1,2,3$), and $\lim_{t\to \infty }\frac{1}{t}\int _{t-\tau }^{t}x_{i}(s)\,\mathrm{d}s=0$ a.s. ($i=1,2,3$) for any constant $\tau >0$. This completes the proof. □

3 Global dynamics

Firstly, on the extinction and persistence and global stability in the mean with probability one, we can establish the following integrated results.

Theorem 1

Assume that $(x_{1}(t),x_{2}(t),x_{3}(t))$ is a global positive solution of model (1). Then we have

(1)
If $\Delta _{11}<0$, then $\lim_{t\to \infty }x_{i}(t)=0$ a.s. for $i=1,2,3$.
(2)
If $\Delta _{11}=0$, then $\lim_{t\to \infty }\langle x_{1}(t) \rangle =0$ and $\lim_{t\to \infty }x_{i}(t)=0$ a.s. for $i=2,3$.
(3)
If $\Delta _{11}>0$ and $\Delta _{22}<0$, then $\lim_{t\to \infty } \langle x_{1}(t)\rangle =\frac{\Delta _{11}}{H_{1}}$ and $\lim_{t\to \infty }x_{i}(t)=0$ a.s. for $i=2,3$.
(4)
If $\Delta _{22}=0$, then $\lim_{t\to \infty }\langle x_{1}(t) \rangle =\frac{\Delta _{11}}{H_{1}}$, $\lim_{t\to \infty }\langle x _{2}(t)\rangle =0$, and $\lim_{t\to \infty }x_{3}(t)=0$ a.s.
(5)
If $\Delta _{22}>0$ and $\Delta _{33}<0$, then $\lim_{t\to \infty } \langle x_{1}(t)\rangle =\frac{\Delta _{21}}{H_{2}}$, $\lim_{t\to \infty }\langle x_{2}(t)\rangle =\frac{\Delta _{22}}{H_{2}}$, and $\lim_{t\to \infty }x_{3}(t)=0$ a.s.
(6)
If $\Delta _{33}=0$ and $a_{33}a_{22}(a_{11}a_{22}+a_{12}a_{21})-a _{12}a_{21}a_{23}a_{32}>0$, then $\lim_{t\to \infty }\langle x_{1}(t) \rangle =\frac{\Delta _{21}}{H_{2}}$, $\lim_{t\to \infty }\langle x _{2}(t)\rangle =\frac{\Delta _{22}}{H_{2}}$, and $\lim_{t\to \infty } \langle x_{3}(t)\rangle =0$ a.s.
(7)
If $\Delta _{33}>0$ and $a_{33}a_{22}(a_{11}a_{22}+a_{12}a_{21})-a _{12}a_{21}a_{23}a_{32}>0$, then
$$ \lim_{t\to \infty }\bigl\langle x_{1}(t)\bigr\rangle = \frac{\Delta _{31}}{H_{3}},\qquad \lim_{t\to \infty }\bigl\langle x_{2}(t)\bigr\rangle =\frac{\Delta _{32}}{H _{3}},\qquad \lim _{t\to \infty }\bigl\langle x_{3}(t)\bigr\rangle = \frac{\Delta _{33}}{H _{3}}\quad \textit{a.s.} $$

Proof

Using Itô’s formula to model (1), we obtain

$$\begin{aligned}& \ln x_{1}(t) = b_{1}t-a_{11} \int _{0}^{t}x_{1}(s) \,\mathrm{d}s-a_{12} \int _{0}^{t} \int _{-\tau _{12}}^{0}x_{2}(s+\theta )\,\mathrm{d}\mu _{12}(\theta )\,\mathrm{d}s +\sigma _{1}B_{1}(t)+\ln x_{1}(0) \\& \hphantom{\ln x_{1}(t)}= b_{1}t-a_{11} \int _{0}^{t}x_{1}(s) \,\mathrm{d}s-a_{12} \int _{0}^{t}x_{2}(s)\,\mathrm{d}s +\phi _{1}(t), \end{aligned}$$

(25)

$$\begin{aligned}& \ln x_{2}(t) = -b_{2}t+a_{21} \int _{0}^{t} \int _{-\tau _{21}}^{0}x_{1}(s+ \theta )\,\mathrm{d}\mu _{21}(\theta )\,\mathrm{d}s-a_{22} \int _{0}^{t}x_{2}(s) \,\mathrm{d}s \\& \hphantom{\ln x_{2}(t) =}{}-a_{23} \int _{0}^{t} \int _{-\tau _{23}}^{0}x_{3}(s+\theta ) \,\mathrm{d}\mu _{23}(\theta )\,\mathrm{d}s+\sigma _{2}B_{2}(t)+\ln x_{2}(0) \\& \hphantom{\ln x_{2}(t)}=-b _{2}t+a_{21} \int _{0}^{t}x_{1}(s)\,\mathrm{d}s -a_{22} \int _{0}^{t}x_{2}(s) \,\mathrm{d}s-a_{23} \int _{0}^{t}x_{3}(s)\,\mathrm{d}s+\phi _{2}(t) \end{aligned}$$

(26)

and

$$\begin{aligned} \ln x_{3}(t) = &-b_{3}t+a_{32} \int _{0}^{t} \int _{-\tau _{32}}^{0}x_{2}(s+ \theta )\,\mathrm{d}\mu _{32}(\theta )\,\mathrm{d}s -a_{33} \int _{0}^{t}x_{3}(s) \,\mathrm{d}s+\sigma _{3}B_{3}(t)+\ln x_{3}(0) \\ =&-b_{3}t+a_{32} \int _{0} ^{t}x_{2}(s) \,\mathrm{d}s-a_{33} \int _{0}^{t}x_{3}(s)\,\mathrm{d}s+\phi _{3}(t), \end{aligned}$$

(27)

where

$$\begin{aligned}& \phi _{1}(t)= \sigma _{1}B_{1}(t)+ \ln x_{1}(0)+a_{12} \int _{-\tau _{12}} ^{0} \int _{t+\theta }^{t}x_{2}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{12}(\theta )\\& \hphantom{\phi _{1}(t)=}{} -a _{12} \int _{-\tau _{12}}^{0} \int _{\theta }^{0}x_{2}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{12}(\theta ), \\& \phi _{2}(t)=\sigma _{2}B_{2}(t)+\ln x_{2}(0) +a _{21} \int _{-\tau _{21}}^{0} \int _{\theta }^{0}x_{1}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{21}(\theta ) \\& \hphantom{\phi _{2}(t)=}{}-a_{21} \int _{-\tau _{21}}^{0} \int _{t+\theta }^{t}x _{1}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{21}(\theta ) \\& \hphantom{\phi _{2}(t)=}{}+a_{23} \int _{-\tau _{23}} ^{0} \int _{t+\theta }^{t}x_{3}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{23}(\theta ) -a _{23} \int _{-\tau _{23}}^{0} \int _{\theta }^{0}x_{3}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{23}(\theta ), \\& \phi _{3}(t)=\sigma _{3}B_{3}(t)+\ln x_{3}(0)+a _{32} \int _{-\tau _{32}}^{0} \int _{\theta }^{0}x_{2}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{32}(\theta ) \\& \hphantom{\phi _{3}(t)=}{} -a_{32} \int _{-\tau _{32}}^{0} \int _{t+\theta }^{t}x _{2}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{32}(\theta ). \end{aligned}$$

Further, we also obtain

$$ \ln x_{1}(t) \leq b_{1}t-a_{11} \int _{0}^{t}x_{1}(s)\,\mathrm{d}s+\sigma _{1}B_{1}(t)+\ln x_{1}(0) $$

(28)

and

$$\begin{aligned} \ln x_{2}(t) \leq &-b_{2}t+a_{21} \int _{0}^{t} \int _{-\tau _{21}}^{0}x _{1}(s+\theta )\,\mathrm{d}\mu _{21}(\theta )\,\mathrm{d}s -a_{22} \int _{0}^{t}x _{2}(s)\,\mathrm{d}s+\sigma _{2}B_{2}(t)+\ln x_{2}(0) \\ =&-b_{2}t+a_{21} \int _{0}^{t}x_{1}(s)\,\mathrm{d}s -a_{22} \int _{0}^{t}x_{2}(s)\,\mathrm{d}s+ \sigma _{2}B_{2}(t)+\ln x_{2}(0) \\ &{}+a_{21} \int _{-\tau _{21}}^{0} \int _{\theta }^{0}x_{1}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{21}(\theta ) -a_{21} \int _{-\tau _{21}}^{0} \int _{t+\theta }^{t}x_{1}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{21}(\theta ). \end{aligned}$$

(29)

Assume $\Delta _{11}\leq 0$. From (28), Lemmas 5 and 6, we can immediately obtain that conclusions (1) and (2) hold.

Assume $\Delta _{11}>0$ and $\Delta _{22}\leq 0$. From (28), Lemmas 5 and 6, we immediately obtain that $\limsup_{t\to \infty } \langle x_{1}(t)\rangle \leq \frac{\Delta _{11}}{H_{1}}$, $\lim_{t\to \infty }x_{2}(t)=0$ or $\lim_{t\to \infty }\langle x_{2}(t) \rangle =0$, and $\lim_{t\to \infty }x_{3}(t)=0$ a.s. For any $\varepsilon >0$ with $b_{1}-a_{12}\varepsilon >0$, we have $\int _{0}^{t}x_{2}(s)\,\mathrm{d}s<\varepsilon t$ a.s. for enough large t, and from (25)

$$ \ln x_{1}(t)\geq (b_{1}-a_{12}\varepsilon )t-a_{11} \int _{0}^{t}x_{1}(s) \,\mathrm{d}s+\phi _{1}(t). $$

Since

$$\begin{aligned}& \int _{-\tau _{12}}^{0} \int _{t+\theta }^{t}x_{2}(s)\,\mathrm{d}s\,\mathrm{d} \mu _{12}(\theta ) \leq \int _{-\tau _{12}}^{0}\,\mathrm{d}\mu _{12}(\theta ) \int _{t-\tau _{12}}^{t}x_{2}(s)\,\mathrm{d}s, \\& \int _{-\tau _{12}}^{0} \int _{\theta }^{0}x_{2}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{12}(\theta )\leq \int _{-\tau _{12}}^{0}\,\mathrm{d}\mu _{12}(\theta ) \int _{-\tau _{12}}^{0}x _{2}(s)\,\mathrm{d}s, \end{aligned}$$

by Lemma 6 we obtain $\lim_{t\to \infty }\frac{1}{t}\int _{-\tau _{12}} ^{0}\int _{t+\theta }^{t}x_{2}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{12}(\theta )=0$ and $\lim_{t\to \infty }\frac{1}{t} \int _{-\tau _{12}}^{0}\int _{\theta }^{0}x_{2}(s)\,\mathrm{d}s\,\mathrm{d}\mu _{12}(\theta ) =0$. Hence, $\lim_{t\to \infty }\frac{\phi _{1}(t)}{t}=0$ a.s. Thus, from Lemma 4 and the arbitrariness of ε we have $\liminf_{t\to \infty }\langle x_{1}(t)\rangle \geq \frac{\Delta _{11}}{H _{1}}$. This shows that $\lim_{t\to \infty }\langle x_{1}(t)\rangle =\frac{ \Delta _{11}}{H_{1}}$.

Assume $\Delta _{33}>0$. From (25)–(27), we obtain

$$ a_{32}\bigl[a_{21}\ln x_{1}(t)+a_{11} \ln x_{2}(t)\bigr]+H_{2}\ln x_{3}(t) = \Delta _{33}t-H_{3} \int _{0}^{t}x_{3}(s)\,\mathrm{d}s+\phi _{4}(t), $$

(30)

where $\phi _{4}(t)=a_{21}a_{32}\phi _{1}(t)+a_{11}a_{32}\phi _{2}(t)+H _{2}\phi _{3}(t)$. By a similar argument as in the above, for $\phi _{1}(t)$, we have $\lim_{t\to \infty }\frac{\phi _{4}(t)}{t}=0$ a.s. For any $\varepsilon >0$ with $\Delta _{33}-2\varepsilon >0$, by Lemma 6, $\ln x_{1}(t)<\frac{ \varepsilon }{a_{32}a_{21}+1}t$ and $\ln x_{2}(t)<\frac{\varepsilon }{a _{32}a_{11}+1}t$ for t enough large. Then from (30) we further have

$$ H_{2}\ln x_{3}(t)>(\Delta _{33}-2\varepsilon )t-H_{3} \int _{0}^{t}x_{3}(s) \,\mathrm{d}s+\phi _{4}(t). $$

Hence, by Lemma 4 and the arbitrariness of ε, we further have

$$ \liminf_{t\to \infty }\bigl\langle x_{3}(t) \bigr\rangle \geq \frac{\Delta _{33}}{H _{3}}. $$

(31)

From (25) and (26), we obtain

$$ a_{22}\ln x_{1}(t)-a_{12}\ln x_{2}(t) =\Delta _{21}t-H_{2} \int _{0}^{t}x _{1}(s)\,\mathrm{d}s+ a_{12}a_{23} \int _{0}^{t}x_{3}(s)\,\mathrm{d}s+\phi _{5}(t), $$

(32)

where $\phi _{5}(t)=a_{22}\phi _{1}(t)-a_{12}\phi _{2}(t)$. Similarly, as in the above for $\phi _{1}(t)$, we can obtain $\lim_{t\to \infty }\frac{ \phi _{5}(t)}{t}=0$ a.s. For any $\varepsilon >0$, from Lemma 6 and the properties of superior limit, we have $\int _{0}^{t}x_{3}(s)\,\mathrm{d}s<( \limsup_{t\to \infty }\langle x_{3}(t)\rangle +\varepsilon )t$ and $\ln x_{2}(t)<\frac{\varepsilon }{a_{12}+1}t$ for enough large t. Then from (32) we further have

$$ a_{22}\ln x_{1}(t)\leq \Delta _{21}t+a_{12}a_{23} \Bigl(\limsup_{t\to \infty }\bigl\langle x_{3}(t)\bigr\rangle + \varepsilon \Bigr)t+\varepsilon t-H_{2} \int _{0} ^{t}x_{1}(s)\,\mathrm{d}s+\phi _{5}(t). $$

From Lemma 4 and the arbitrariness of ε it follows that

$$ \limsup_{t\to \infty }\bigl\langle x_{1}(t) \bigr\rangle \leq \frac{\Delta _{21}+a _{12}a_{23}\limsup_{t\to \infty }\langle x_{3}(t)\rangle }{H_{2}} \quad \textit{a.s.} $$

(33)

Combining (31), for any $\varepsilon >0$ enough small, when t is enough large, we have

$$ \int _{0}^{t}x_{3}(s)\,\mathrm{d}s>\biggl( \frac{\Delta _{33}}{H_{3}}-\varepsilon \biggr)t,\qquad \int _{0}^{t}x_{1}(s)\,\mathrm{d}s< \biggl( \frac{\Delta _{21}+a_{12}a_{23} \limsup_{t\to \infty }\langle x_{3}(t)\rangle }{H_{2}}+\varepsilon \biggr)t. $$

Hence, from (29) we further have

$$\begin{aligned} \ln x_{2}(t) \leq & -b_{2}t + \biggl(\frac{a_{21}(\Delta _{21}+a_{12}a_{23} \limsup_{t\to \infty }\langle x_{3}(t)\rangle )}{H_{2}}+\varepsilon \biggr)t \\ &{}-a_{23}\biggl(\frac{\Delta _{33}}{H_{3}} -\varepsilon \biggr)t-a_{22} \int _{0} ^{t}x_{2}(s)\,\mathrm{d}s+\phi _{2}(t). \end{aligned}$$

(34)

We have $\lim_{t\to \infty }\frac{\phi _{2}(t)}{t}=0$ a.s. by Lemma 6. From (31), we obtain

$$\begin{aligned}& -b_{2}+\frac{a_{21}(\Delta _{21}+a_{12}a_{23}\limsup_{t\to \infty } \langle x_{3}(t)\rangle )}{H_{2}}-a_{23}\frac{\Delta _{33}}{H_{3}} \\& \quad \geq -b_{2}+a_{21}\frac{\Delta _{21}}{H_{2}}-a_{23} \frac{\Delta _{33}}{H _{3}}+\frac{a_{21}a_{12}a_{23}\Delta _{33}}{H_{2}H_{3}}=\frac{a_{22} \Delta _{32}}{H_{3}}>0. \end{aligned}$$

Hence, from (34), Lemma 4, and the arbitrariness of ε, we have

$$\begin{aligned} a_{22}\limsup_{t\to \infty }\bigl\langle x_{2}(t)\bigr\rangle \leq& \biggl(-b_{2}+ \frac{a _{21}(\Delta _{21}+a_{12}a_{23}\limsup_{t\to \infty }\langle x_{3}(t) \rangle }{H_{2}}-a_{23}\frac{\Delta _{33}}{H_{3}}\biggr) \\ \triangleq& M \quad \textit{a.s.} \end{aligned}$$

(35)

For any $\varepsilon >0$, when t is enough large, we have $\int _{0}^{t}x_{2}(s)\,\mathrm{d}s<(\frac{M}{a_{22}}+\varepsilon )t$. Then from (27) it follows that

$$\begin{aligned} \ln x_{3}(t) \leq & -b_{3}t+a_{32} \biggl(\frac{M}{a_{22}}+\varepsilon \biggr)t -a _{33} \int _{0}^{t}x_{3}(s)\,\mathrm{d}s+\phi _{3}(t) \\ \leq &-b_{3}t+a_{32} \varepsilon t+ \frac{a_{32}}{a_{22}} \biggl(-b_{2}+\frac{a_{21}(\Delta _{21}+a _{12}a_{23}\limsup_{t\to \infty }\langle x_{3}(t)\rangle )}{H_{2}}-a _{23}\frac{\Delta _{33}}{H_{3}} \biggr)t \\ &{}-a_{33} \int _{0}^{t}x_{3}(s) \,\mathrm{d}s+\phi _{3}(t). \end{aligned}$$

(36)

We have $\lim_{t\to \infty }\frac{\phi _{3}(t)}{t}=0$ a.s. by Lemma 6. From (31), we also have

$$\begin{aligned}& -b_{3}+ \frac{a_{32}}{a_{22}}\biggl(-b_{2}+ \frac{a_{21}(\Delta _{21}+a_{12}a _{23}\limsup_{t\to \infty }\langle x_{3}(t)\rangle )}{H_{2}}-a_{23}\frac{ \Delta _{33} }{H_{3}}\biggr) \\& \quad \geq -b_{3}+\frac{a_{32}}{a_{22}}\biggl(-b_{2}+a _{21}\frac{\Delta _{21}}{H_{2}} -a_{23}\frac{\Delta _{33}}{H_{3}}+ \frac{a _{21}a_{12}a_{23}\Delta _{33}}{H_{2}H_{3}}\biggr)=a_{33}\frac{\Delta _{33}}{H _{3}}>0. \end{aligned}$$

Hence, from (36), Lemma 4, and the arbitrariness of ε, one can derive that

$$\begin{aligned}& a_{33}\limsup_{t\to \infty }\bigl\langle x_{3}(t)\bigr\rangle \\& \quad \leq -b_{3}+\frac{a _{32}}{a_{22}}\biggl(-b_{2}+a_{21} \frac{\Delta _{21}}{H_{2}}+\frac{a_{12}a _{21}a_{23}\limsup_{t\to \infty }\langle x_{3}(t)\rangle }{H_{2}}-a _{23}\frac{\Delta _{33}}{H_{3}}\biggr). \end{aligned}$$

That is equivalent to the following equation:

$$\begin{aligned}& \bigl[a_{33}a_{22}(a_{11}a_{22}+a_{12}a_{21})-a_{12}a_{21}a_{23}a_{32} \bigr] \limsup_{t\to \infty }\bigl\langle x_{3}(t)\bigr\rangle \\& \quad \leq \bigl[a_{33}a_{22}(a _{11}a_{22}+a_{12}a_{21})-a_{12}a_{21}a_{23}a_{32} \bigr]\times \frac{ \Delta _{33}}{H_{3}}. \end{aligned}$$

Hence, we obtain $\limsup_{t\to \infty }\langle x_{3}(t)\rangle \leq \frac{\Delta _{33}}{H_{3}}$ a.s. Combining (31), we finally obtain $\lim_{t\to \infty }\langle x_{3}(t)\rangle =\frac{\Delta _{33}}{H _{3}}$ a.s.

From (33) and (35) we can obtain

$$ \limsup_{t\to \infty }\bigl\langle x_{1}(t) \bigr\rangle \leq \frac{b_{1}(a_{22}a _{33}+a_{32}a_{23})+b_{2}a_{33}a_{12}-b_{3}a_{12}a_{23}}{a_{11}a_{22}a _{33}+a_{12}a_{21}a_{33}+a_{11}a_{32}a_{23}} =\frac{\Delta _{31}}{H _{3}}\quad \textit{a.s.} $$

(37)

and

$$ \limsup_{t\to \infty }\bigl\langle x_{2}(t) \bigr\rangle \leq \frac{b_{1}a_{21}a _{33}-b_{2}a_{33}a_{11}+b_{3}a_{11}a_{23}}{a_{11}a_{22}a_{33}+a_{12}a _{21}a_{33}+a_{11}a_{32}a_{23}} =\frac{\Delta _{32}}{H_{3}}\quad \textit{a.s.} $$

(38)

For any $\varepsilon >0$, from Lemma 6 there is $T>0$ such that, for any $t>T$,

$$ \int _{0}^{t}x_{3}(s)\,\mathrm{d}s< \biggl( \frac{\Delta _{33}}{H_{3}}+\varepsilon \biggr)t,\qquad \ln x_{1}(t)< \frac{\varepsilon }{a_{21}+1}t. $$

(39)

From (25) and (26), we obtain

$$ \begin{aligned} a_{21}\ln x_{1}(t)+a_{11}\ln x_{2}(t)=\Delta _{22}t-H_{2} \int _{0}^{t}x _{2}(s) \,\mathrm{d}s-a_{11}a_{23} \int _{0}^{t}x_{3}(s)\,\mathrm{d}s+\phi _{6}(t), \end{aligned} $$

(40)

where $\phi _{6}(t)=a_{21}\phi _{1}(t)+a_{11}\phi _{2}(t)$. We have $\lim_{t\to \infty }\frac{\phi _{6}(t)}{t}=0$ a.s. by Lemma 6. Substituting (39) into (40), we have, when $t>T$,

$$ a_{11}\ln x_{2}(t) \geq \Delta _{22}t-a_{11}a_{23} \biggl(\frac{\Delta _{33}}{H _{3}}+\varepsilon \biggr)t-\varepsilon t-H_{2} \int _{0}^{t}x_{2}(s)\,\mathrm{d}s+ \phi _{6}(t). $$

From Lemma 4 and the arbitrariness of ε, we have $\liminf_{t\to \infty }\langle x_{2}(t)\rangle \geq \frac{\Delta _{32}}{H _{3}}$ a.s. Combining (38), we finally obtain $\lim_{t\to \infty }\langle x_{2}(t)\rangle =\frac{\Delta _{32}}{H_{3}} $ a.s.

For any $\varepsilon >0$, from (38) when t is enough large we have $\int _{0}^{t}x_{2}(s)\,\mathrm{d}s< (\frac{\Delta _{32}}{H_{3}}+ \varepsilon )t$. Then from (25) it follows that

$$ \ln x_{1}(t) \geq b_{1}t-a_{11} \int _{0}^{t}x_{1}(s) \,\mathrm{d}s-a_{12}\biggl( \frac{ \Delta _{32}}{H_{3}}+\varepsilon \biggr)t+\phi _{1}(t). $$

From Lemma 4 and the arbitrariness of ε, we have $\liminf_{t\to \infty }\langle x_{1}(t)\rangle \geq \frac{\Delta _{31}}{H _{3}}$. Combining (37), we finally obtain $\lim_{t\to \infty }\langle x_{1}(t)\rangle =\frac{\Delta _{31}}{H_{3}}$ a.s.

Assume $\Delta _{33}=0$. Then we can have $\Delta _{22}>0$ and $\Delta _{11}>0$. By a similar argument as in the above for case $\Delta _{33}>0$, we can obtain

$$ a_{33}\limsup_{t\to \infty }\bigl\langle x_{3}(t) \bigr\rangle \leq -b_{3}+\frac{a _{32}}{a_{22}}\biggl(-b_{2}+a_{21} \frac{\Delta _{21}}{H_{2}} +\frac{a_{12}a _{21}a_{23}\limsup_{t\to \infty }\langle x_{3}(t)\rangle }{H_{2}}\biggr). $$

That is equivalent to the following equation:

$$ \bigl[a_{33}a_{22}(a_{11}a_{22}+a_{12}a_{21})-a_{12}a_{21}a_{23}a_{32} \bigr] \limsup_{t\to \infty }\bigl\langle x_{3}(t)\bigr\rangle \leq 0. $$

Therefore, we finally have $\lim_{t\to +\infty }\langle x_{3}(t) \rangle = 0$. Thus, for any $\varepsilon >0$, there is $T>0$ such that $\int _{0}^{t}x_{3}(s)\,\mathrm{d}s<\varepsilon t$ for all $t>T$. Hence, from (39) and (40) we further obtain as $t>T$

$$ a_{11}\ln x_{2}(t)\geq \Delta _{22}t-a_{11}a_{23} \varepsilon t-\varepsilon t-H_{2} \int _{0}^{t}x_{2}(s)\,\mathrm{d}s+\phi _{6}(t). $$

From Lemma 4 and the arbitrariness of ε, we have

$$ \liminf_{t\to \infty }\bigl\langle x_{2}(t) \bigr\rangle \geq \frac{\Delta _{22}}{H _{2}} \quad \textit{a.s.} $$

(41)

Using the same method as in the proof of $\liminf_{t\to \infty } \langle x_{1}(t)\rangle \geq \frac{\Delta _{31}}{H_{3}}$ in the above, we can successively prove $\limsup_{t\to \infty }\langle x_{1}(t) \rangle \leq \frac{\Delta _{21}}{H_{2}}$ a.s., $\limsup_{t\to \infty }\langle x_{2}(t)\rangle \leq \frac{\Delta _{22}}{H_{2}}$ a.s., and $\liminf_{t\to \infty }\langle x_{1}(t)\rangle \geq \frac{\Delta _{21}}{H _{2}}$ a.s. Combining (41), we finally obtain $\lim_{t\to \infty }\langle x_{2}(t)\rangle =\frac{\Delta _{22}}{H_{2}} $ a.s. and $\lim_{t\to \infty }\langle x_{1}(t)\rangle =\frac{ \Delta _{21}}{H_{2}}$ a.s.

Assume $\Delta _{22}>0$ and $\Delta _{33}<0$. From (30) we directly obtain

$$ a_{32}\bigl[a_{21}\ln x_{1}(t)+a_{11} \ln x_{2}(t)\bigr]+H_{2}\ln x_{3}(t)\leq \Delta _{33}t+\phi _{4}(t). $$

Hence,

$$ \limsup_{t\to \infty }\frac{1}{t}\bigl(a_{21}a_{32} \ln x_{1}(t)+a_{11}a _{32}\ln x_{2}(t)+H_{2} \ln x_{3}(t)\bigr)\leq \Delta _{33}< 0. $$

This shows $\lim_{t\to \infty }(x_{1}(t))^{a_{21}a_{32}}(x_{2}(t))^{a _{11}a_{32}}(x_{3}(t))^{H_{2}}=0$, which implies that there is $i\in \{1,2,3\}$ such that

$$ \lim_{t\to \infty }x_{i}(t)=0. $$

(42)

For $1\leq i\leq j\leq 3$, similarly to the above arguments for cases $\Delta _{11}\leq 0$, and $\Delta _{11}>0$ and $\Delta _{22}\leq 0$, we can easily prove that if $\lim_{t\to \infty }x_{i}(t)=0$ a.s., then $\lim_{t\to +\infty }x_{j}(t)=0$ a.s. Therefore, from (42) we finally obtain $\lim_{t\to \infty }x_{3}(t)=0$ a.s. Consequently, $\lim_{t\to \infty }\langle x_{3}(t)\rangle =0$ a.s. By a similar argument as in the above for case $\Delta _{33}=0$, we also know $\lim_{t\to \infty }\langle x_{1}(t)\rangle = \frac{\Delta _{21}}{H_{2}}$ and $\lim_{t\to \infty }\langle x_{2}(t) \rangle =\frac{\Delta _{22}}{H_{2}}$. This completes the proof. □

Next, we can establish the following result on the global attractivity in the expectation for any global positive solutions of model (1).

Theorem 2

Let $(x_{1}(t;\phi ),x_{2}(t;\phi ),x_{3}(t;\phi ))$ and $(y_{1}(t; \phi ^{*}),y_{2}(t;\phi ^{*}),y_{3}(t;\phi ^{*}))$ be two solutions of model (1) with initial values $\phi ,\phi ^{*}\in C([-\gamma ,0],R _{+}^{3}))$. Assume that there are positive constants $w_{1}$, $w_{2}$, and $w_{3}$ such that

$$ w_{1}a_{11}-w_{2}a_{21}>0, \qquad w_{2}a_{22}-w_{1}a_{12}-w_{3}a_{32}>0, \qquad w_{3}a_{33}-w_{2}a_{23}>0. $$

Then

$$ \lim_{t\to \infty }E\sqrt{ \bigl\vert x_{1}(t;\phi )-x_{1}\bigl(t;\phi ^{*}\bigr) \bigr\vert ^{2}+ \bigl\vert x_{2}(t;\phi )-x_{2}\bigl(t;\phi ^{*} \bigr) \bigr\vert ^{2}+ \bigl\vert x_{3}(t;\phi )-x_{3}\bigl(t;\phi ^{*}\bigr) \bigr\vert ^{2}}=0. $$

Proof

We only need to show

$$ \lim_{t\to \infty }E \bigl\vert x_{i}(t; \phi )-x_{i}\bigl(t;\phi ^{*}\bigr) \bigr\vert =0, \quad i=1,2,3. $$

(43)

Define functions as follows:

$$ V_{i}(x_{i})= \bigl\vert \ln x_{i}(t;\phi )- \ln y_{i}\bigl(t;\phi ^{*}\bigr) \bigr\vert ,\quad i=1,2,3. $$

Applying Itô’s formula, we obtain

$$\begin{aligned}& \mathcal{L}V_{1}(x_{1})\leq -a_{11} \bigl\vert x_{1}(t;\phi )-y_{1}\bigl(t; \phi ^{*}\bigr) \bigr\vert \\& \hphantom{\mathcal{L}V_{1}(x_{1})\leq}{}+a _{12} \int _{-\tau _{12}}^{0} \bigl\vert x_{2}(t+\theta ;\phi )-y_{2}\bigl(t+\theta ;\phi ^{*}\bigr) \bigr\vert \,\mathrm{d}\mu _{12}(\theta ), \end{aligned}$$

(44)

$$\begin{aligned}& \mathcal{L}V_{2}(x_{2}) \leq -a_{22} \bigl\vert x_{2}(t;\phi )-y_{2}\bigl(t; \phi ^{*}\bigr) \bigr\vert +a_{21} \int _{-\tau _{21}}^{0} \bigl\vert x_{1}(t+\theta ;\phi )-y_{1}\bigl(t+ \theta ;\phi ^{*}\bigr) \bigr\vert \,\mathrm{d}\mu _{21}(\theta ) \\& \hphantom{\mathcal{L}V_{2}(x_{2}) \leq}{}+a_{23} \int _{-\tau _{23}} ^{0} \bigl\vert x_{3}(t+\theta ;\phi )-y_{3}\bigl(t+\theta ;\phi ^{*}\bigr) \bigr\vert \,\mathrm{d}\mu _{23}( \theta ), \end{aligned}$$

(45)

and

$$\begin{aligned} \mathcal{L}V_{3}(x_{3}) \leq& -a_{33} \bigl\vert x_{3}(t;\phi )-y_{3}\bigl(t; \phi ^{*}\bigr) \bigr\vert \\ &{}+a _{32} \int _{-\tau _{32}}^{0} \bigl\vert x_{2}(t+\theta ;\phi )-y_{2}\bigl(t+\theta ;\phi ^{*}\bigr) \bigr\vert \,\mathrm{d}\mu _{32}(\theta ). \end{aligned}$$

(46)

Define function as follows:

$$ V(t)=w_{1}V_{1}(x_{1})+w_{2}V_{2}(x_{2})+w_{3}V_{3}(x_{3})+V_{4}(t), $$

(47)

where

$$\begin{aligned} V_{4}(t) = &w_{1}a_{12} \int _{-\tau _{12}}^{0} \int _{t+\theta }^{t} \bigl\vert x_{2}(s; \phi )-y_{2}\bigl(s;\phi ^{*}\bigr) \bigr\vert \,\mathrm{d}s\,\mathrm{d} \mu _{12}(\theta ) \\ &{}+w_{2}a _{21} \int _{-\tau _{21}}^{0} \int _{t+\theta }^{t} \bigl\vert x_{1}(s;\phi )-y_{1}\bigl(s; \phi ^{*}\bigr) \bigr\vert \,\mathrm{d}s \,\mathrm{d}\mu _{21}(\theta ) \\ &{}+w_{2}a_{23} \int _{-\tau _{23}}^{0} \int _{t+\theta }^{t} \bigl\vert x_{3}(s;\phi )-y_{3}\bigl(s;\phi ^{*}\bigr) \bigr\vert \,\mathrm{d}s\,\mathrm{d} \mu _{23}(\theta ) \\ &{}+w_{3}a_{32} \int _{-\tau _{32}}^{0} \int _{t+\theta }^{t} \bigl\vert x_{2}(s;\phi )-y_{2}\bigl(s;\phi ^{*}\bigr) \bigr\vert \,\mathrm{d}s\,\mathrm{d} \mu _{32}(\theta ). \end{aligned}$$

(48)

From (44)–(48) we obtain

$$\begin{aligned} \mathcal{L}V(t) = &w_{1}\mathcal{L}V_{1}(x_{1})+w_{2} \mathcal{L}V_{2}(x _{2})+w_{3}\mathcal{L}V_{3}(x_{3}) + \frac{\,\mathrm{d}V_{4}(t;\phi ,\phi ^{*})}{\mathrm{d}t} \\ \leq &-(w_{1}a _{11}-w_{2}a_{21}) \bigl\vert x_{1}(t;\phi )-y_{1}\bigl(t;\phi ^{*} \bigr) \bigr\vert \\ &{}-(w_{2}a_{22}-w _{1}a_{12}-w_{3}a_{32}) \bigl\vert x_{2}(t;\phi )-y_{2}\bigl(t;\phi ^{*} \bigr) \bigr\vert \\ &{}-(w_{3}a _{33}-w_{2}a_{23}) \bigl\vert x_{3}(t;\phi )-y_{3}\bigl(t;\phi ^{*}\bigr) \bigr\vert . \end{aligned}$$

Hence, we have

$$\begin{aligned} E\bigl[V(t)\bigr] \leq & E\bigl[V(0)\bigr]-(w_{1}a_{11}-w_{2}a_{21}) \int _{0}^{t}E\bigl[ \bigl\vert x_{1}(s; \phi )-y_{1}\bigl(s;\phi ^{*}\bigr) \bigr\vert \bigr]\,\mathrm{d}s \\ &{}-(w_{2}a_{22}-w_{1}a_{12}-w _{3}a_{32}) \int _{0}^{t}E\bigl[\big| x_{2}(s;\phi )-y_{2}\bigl(s;\phi ^{*}\bigr)\big|\bigr]\,\mathrm{d}s \\ &{}-(w_{3}a_{33}-w_{2}a_{23}) \int _{0}^{t}E\bigl[ \bigl\vert x_{3}(s; \phi )-y_{3}\bigl(s; \phi ^{*}\bigr) \bigr\vert \bigr] \,\mathrm{d}s, \end{aligned}$$

which implies

$$ \int _{0}^{t}E\bigl[ \bigl\vert x_{i}(s;\phi )-y_{i}\bigl(s;\phi ^{*}\bigr) \bigr\vert \bigr]\,\mathrm{d}s< +\infty ,\quad i=1,2,3. $$

(49)

Define functions

$$ F_{i}(t)=E\bigl[ \bigl\vert x_{i}(t;\phi )-y_{i}\bigl(t;\phi ^{*}\bigr) \bigr\vert \bigr], \quad i=1,2,3. $$

Then, for any $t_{1},t_{2}\in [0,+\infty )$, we obtain, for each $i=1,2,3$,

$$\begin{aligned} \bigl\vert F_{i}(t_{2})-F_{i}(t_{1}) \bigr\vert = & \bigl\vert E\bigl[ \bigl\vert x_{i}(t_{2}; \phi )-y_{i}\bigl(t_{2}; \phi ^{*}\bigr) \bigr\vert - \bigl\vert x_{i}(t_{1};\phi )-y_{i} \bigl(t_{1};\phi ^{*}\bigr) \bigr\vert \bigr] \bigr\vert \\ \leq & E\bigl[ \bigl\vert \bigl(x _{i}(t_{2};\phi )-y_{i}\bigl(t_{2};\phi ^{*}\bigr)\bigr)- \bigl(x_{i}(t_{1};\phi )-y_{i}\bigl(t _{1};\phi ^{*}\bigr)\bigr) \bigr\vert \bigr] \\ \leq & E\bigl[ \bigl\vert x_{i}(t_{2};\phi )-x_{i}(t_{1};\phi ) \bigr\vert \bigr]+E\bigl[ \bigl\vert y_{i}\bigl(t_{2};\phi ^{*}\bigr)-y _{i}\bigl(t_{1};\phi ^{*}\bigr) \bigr\vert \bigr]. \end{aligned}$$

(50)

From model (1), applying Itô’s formula, we have

$$\begin{aligned}& \begin{aligned} &x_{1}(t_{2};\phi )-x_{1}(t_{1};\phi ) \\ &\quad = \int _{t_{1}}^{t_{2}}x_{1}(s; \phi ) \biggl[r_{1}-h_{1}-a_{11}x_{1}(s;\phi )-a_{12} \int _{-\tau _{12}}^{0}x _{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}(\theta )\biggr]\,\mathrm{d}s \\ &\qquad {}+ \int _{t_{1}} ^{t_{2}}\sigma _{1}x_{1}(s; \phi )\,\mathrm{d}B_{1}(s), \\ &x_{2}(t_{2}; \phi )-x_{2}(t_{1};\phi ) \\ &\quad = \int _{t_{1}}^{t_{2}}x_{2}(s;\phi ) \biggl[-r_{2}-h _{2} +a_{21} \int _{-\tau _{21}}^{0}x_{1}(s+\theta ;\phi ) \,\mathrm{d}\mu _{21}(\theta )-a_{22}x_{2}(s;\phi ) \\ &\qquad {}-a_{23} \int _{-\tau _{23}}^{0}x _{3}(s+\theta ;\phi ) \,\mathrm{d}\mu _{23}(\theta )\biggr]\,\mathrm{d}s+ \int _{t_{1}} ^{t_{2}}\sigma _{2}x_{2}(s; \phi )\,\mathrm{d}B_{2}(s), \\ &x_{3}(t_{2}; \phi )-x_{3}(t_{1};\phi ) \\ &\quad = \int _{0}^{t}x_{3}(s;\phi ) \biggl[-r_{3}-h_{3}+a _{32} \int _{-\tau _{32}}^{0}x_{2}(s+\theta ;\phi ) \,\mathrm{d}\mu _{32}( \theta )-a_{33}x_{3}(s)\biggr] \,\mathrm{d}s \\ &\qquad {}+ \int _{t_{1}}^{t_{2}}\sigma _{3}x _{3}(s;\phi )\,\mathrm{d}B_{3}(s). \end{aligned} \end{aligned}$$

(51)

For any $t_{2}>t_{1}$ and $p>1$, using Hölder’s inequality, from the first equation of (51), we have

$$\begin{aligned}& \bigl(E\bigl[ \bigl\vert x_{1}(t_{2}; \phi )-x_{1}(t_{1};\phi ) \bigr\vert \bigr] \bigr)^{p} \\& \quad \leq E\bigl[ \bigl\vert x_{1}(t _{2};\phi )-x_{1}(t_{1};\phi ) \bigr\vert ^{p}\bigr] \\& \quad \leq E\biggl[\biggl( \int _{t_{1}}^{t_{2}}x _{1}(s;\phi ) \biggl\vert r_{1}-h_{1}-a_{11}x_{1}(s;\phi )-a_{12} \int _{-\tau _{12}} ^{0}x_{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}(\theta ) \biggr\vert \,\mathrm{d}s \\& \qquad {}+ \biggl\vert \int _{t _{1}}^{t_{2}}\sigma _{1}x_{1}(s; \phi )\,\mathrm{d}B_{1}(s) \biggr\vert \biggr)^{p}\biggr] \\& \quad \leq 2^{p}E\biggl[\biggl( \int _{t_{1}}^{t_{2}}x_{1}(s;\phi ) \biggl\vert r_{1}-h_{1}-a_{11}x_{1}(s; \phi )-a_{12} \int _{-\tau _{12}}^{0}x_{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}( \theta ) \biggr\vert \,\mathrm{d}s\biggr)^{p}\biggr] \\& \qquad {}+2^{p}E\biggl[ \biggl\vert \int _{t_{1}}^{t_{2}}\sigma _{1}x _{1}(s;\phi )\,\mathrm{d}B_{1}(s) \biggr\vert ^{p} \biggr]. \end{aligned}$$

(52)

Using Hölder’s inequality again, we also have

$$\begin{aligned}& E\biggl[\biggl( \int _{t_{1}}^{t_{2}}x_{1}(s;\phi ) \biggl\vert r_{1}-h_{1}-a_{11}x_{1}(s; \phi )-a_{12} \int _{-\tau _{12}}^{0}x_{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}( \theta ) \biggr\vert \,\mathrm{d}s\biggr)^{p}\biggr] \\& \quad \leq E\biggl[\biggl( \int _{t_{1}}^{t_{2}}\biggl( \vert r_{1}-h_{1} \vert x_{1}(s;\phi )+a_{11}x _{1}^{2}(s; \phi ) \\& \qquad {}+a_{12} \int _{-\tau _{12}}^{0}x_{1}(s;\phi )x_{2}(s+ \theta ;\phi )\,\mathrm{d}\mu _{12}(\theta )\biggr)\,\mathrm{d}s \biggr)^{p}\biggr] \\& \quad \leq (t_{2}-t_{1})^{p-1}E\biggl[ \int _{t_{1}}^{t_{2}}\biggl( \vert r_{1}-h_{1} \vert x_{1}(s; \phi )+a_{11}x_{1}^{2}(s; \phi ) \\& \qquad {} +a_{12} \int _{-\tau _{12}}^{0}x_{1}(s;\phi )x_{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}(\theta ) \biggr)^{p}\,\mathrm{d}s\biggr] \\& \quad \leq (t_{2}-t_{1})^{p-1}E\biggl[ \int _{t_{1}}^{t_{2}}3^{p}\biggl( \vert r_{1}-h_{1} \vert ^{p} x_{1}^{p}(s; \phi )+a_{11}^{p}x_{1}^{2p}(s;\phi ) \\& \qquad {} +\biggl(a_{12} \int _{-\tau _{12}}^{0}x_{1}(s;\phi )x_{2}(s+\theta ; \phi )\,\mathrm{d}\mu _{12}(\theta ) \biggr)^{p}\biggr)\,\mathrm{d}s\biggr] \\& \quad =3^{p}(t_{2}-t_{1})^{p-1} \vert r_{1}-h_{1} \vert ^{p} \int _{t_{1}}^{t_{2}}E\bigl[x _{1}^{p}(s; \phi )\bigr]\,\mathrm{d}s+3^{p}a_{11}^{p}(t_{2}-t_{1})^{p-1} \int _{t_{1}}^{t_{2}}E\bigl[x_{1}^{2p}(s; \phi )\bigr]\,\mathrm{d}s \\& \qquad {} +3^{p}(t_{2}-t_{1})^{p-1}E \biggl[ \int _{t_{1}}^{t_{2}}\biggl(a_{12} \int _{-\tau _{12}} ^{0}x_{1}(s;\phi ) x_{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}(\theta ) \biggr)^{p} \,\mathrm{d}s\biggr] \end{aligned}$$

(53)

and

$$\begin{aligned}& E\biggl[ \int _{t_{1}}^{t_{2}}\biggl(a_{12} \int _{-\tau _{12}}^{0}x_{1}(s;\phi )x _{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}(\theta )\biggr)^{p} \,\mathrm{d}s\biggr] \\& \quad \leq E\biggl[ \int _{t_{1}}^{t_{2}}\biggl(\frac{1}{2}a_{12}x_{1}^{2}(s; \phi ) +\frac{1}{2}a _{12} \int _{-\tau _{12}}^{0}x_{2}^{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}(\theta )\biggr)^{p}\,\mathrm{d}s\biggr] \\& \quad \leq E\biggl[ \int _{t_{1}}^{t_{2}}\biggl(a_{12}^{p}x_{1}^{2p}(s; \phi )+\biggl(a_{12} \int _{-\tau _{12}}^{0}x_{2}^{2}(s+\theta ;\phi )\,\mathrm{d}\mu _{12}( \theta )\biggr)^{p}\biggr)\,\mathrm{d}s\biggr] \\& \quad \leq E\biggl[ \int _{t_{1}}^{t_{2}}\biggl(a_{12}^{p}x _{1}^{2p}(s;\phi ) +a_{12}^{p-1} \int _{-\tau _{12}}^{0}x_{2}^{2p}(s+ \theta ;\phi )\,\mathrm{d}\mu _{12}(\theta )\biggr)\,\mathrm{d}s\biggr] \\& \quad =a_{12}^{p} \int _{t_{1}}^{t_{2}}E\bigl[x_{1}^{2p}(s; \phi )\bigr]\,\mathrm{d}s+a_{12}^{p-1} \int _{t_{1}}^{t_{2}} \int _{-\tau _{12}}^{0}E\bigl[x_{2}^{2p}(s+ \theta ; \phi )\bigr]\,\mathrm{d}\mu _{12}(\theta )\,\mathrm{d}s. \end{aligned}$$

(54)

In view of Theorem 7.1 in [24], for any $t_{2}>t_{1}$ and $1< p\leq 2$, we obtain

$$ E\biggl[ \biggl\vert \int _{t_{1}}^{t_{2}}\sigma _{1}x_{1}(s; \phi )\,\mathrm{d}B_{1}(s) \biggr\vert ^{p}\biggr] \leq \bigl\vert \sigma _{1}^{p} \bigr\vert \biggl( \frac{p(p-1)}{2}\biggr)^{\frac{p}{2}}(t_{2}-t_{1})^{ \frac{p-2}{2}} \int _{t_{1}}^{t_{2}}E\bigl[x_{1}^{p}(s; \phi )\bigr]\,\mathrm{d}s. $$

(55)

From Lemma 3, there exist $K_{1}^{**}(p)>0$, $K_{2}^{**}(p)>0$, and $K_{3}^{**}(p)>0$ such that $\sup_{t\geq {-\gamma }}E[x_{1}^{p}(t)] \leq K_{1}^{**}(p)$, $\sup_{t\geq {-\gamma }}E[x_{2}^{p}(t)]\leq K _{2}^{**}(p)$, and $\sup_{t\geq {-\gamma }}E[x_{3}^{p}(t)]\leq K_{3} ^{**}(p)$. Therefore, from (52)–(55) there exists $\delta >0$ such that, for any $t_{1}\geq 0$, $t_{2}\geq 0$, and $1< p\leq 2$ with $| t_{2}-t_{1}|\leq \delta $,

$$\begin{aligned}& \bigl(E\bigl[ \bigl\vert x_{1}(t_{2};\phi )-x_{1}(t_{1};\phi ) \bigr\vert \bigr] \bigr)^{p} \\& \quad \leq 2^{p}\biggl[ \bigl\vert \sigma _{1}^{p} \bigr\vert \biggl(\frac{p(p-1)}{2}\biggr)^{\frac{p}{2}}(t_{2}-t_{1})^{ \frac{p}{2}}K_{1}^{**}(p) \biggr]+2^{p}\bigl[3^{p}(t_{2}-t_{1})^{p} \vert r_{1}-h_{1} \vert ^{p}K _{1}^{**}(p) \\& \qquad {}+3^{p}a_{11}^{p}(t_{2}-t_{1})^{p}K_{1}^{**}(2p) \bigr]+2^{p}3^{p}(t _{2}-t_{1})^{p}a_{12}^{p} \bigl[K_{1}^{**}(2p)+K_{2}^{**}(2p)\bigr] \\& \quad \leq M _{1}^{**} \vert t_{2}-t_{1} \vert ^{\frac{p}{2}}, \end{aligned}$$

where

$$\begin{aligned} M_{1}^{**} = & \bigl\vert \sigma _{1}^{p} \bigr\vert \bigl(2p(p-1)\bigr)^{\frac{p}{2}}K_{1}^{**}(p)+[36 \delta ]^{\frac{p}{2}}\bigl[ \vert r_{1}-h_{1} \vert ^{p}K_{1}^{**}(p)+a_{11}^{p}K _{1}^{**}(2p)\bigr] \\ &{}+[36\delta ]^{\frac{p}{2}}a_{12}^{p} \bigl[K_{1}^{**}(2p)+K _{2}^{**}(2p) \bigr]. \end{aligned}$$

Similarly, we also obtain

$$ \bigl(E\bigl[ \bigl\vert y_{1}\bigl(t_{2};\phi ^{*}\bigr)-y_{1}\bigl(t_{1};\phi ^{*} \bigr) \bigr\vert \bigr]\bigr)^{p}\leq M_{1}^{**} \vert t_{2}-t_{1} \vert ^{\frac{p}{2}} $$

for any $t_{1}\geq 0$, $t_{2}\geq 0$ with $| t_{2}-t_{1}|\leq \delta $ and $1< p\leq 2$. Thus, from (50), we obtain

$$\begin{aligned} \bigl\vert F_{1}(t_{2})-F_{1}(t_{1}) \bigr\vert \leq & E\bigl[ \bigl\vert x_{1}(t_{2};\phi )-x_{1}(t_{1}; \phi ) \bigr\vert \bigr]+E\bigl[ \bigl\vert y_{1}\bigl(t_{2};\phi ^{*} \bigr)-y_{1}\bigl(t_{1};\phi ^{*}\bigr) \bigr\vert \bigr] \\ \leq &2\bigl(M _{1}^{**}\bigr)^{\frac{1}{p}}\sqrt{ \vert t_{2}-t_{1} \vert }. \end{aligned}$$

(56)

Using a similar argument, for $F_{2}(t)$ and $F_{3}(t)$ we can also obtain that there is $\delta >0$ for any $t_{1}\geq 0$, $t_{2}\geq 0$ with $| t_{2}-t_{1}|\leq \delta $ and $1< p\leq 2$

$$ \bigl\vert F_{2}(t_{2})-F_{2}(t_{1}) \bigr\vert \leq 2\bigl(M_{2}^{**}\bigr)^{\frac{1}{p}} \sqrt{ \vert t_{2}-t_{1} \vert } $$

(57)

and

$$ \bigl\vert F_{3}(t_{2})-F_{3}(t_{1}) \bigr\vert \leq 2\bigl(M_{3}^{**}\bigr)^{\frac{1}{p}} \sqrt{ \vert t_{2}-t_{1} \vert }, $$

(58)

where

$$\begin{aligned} M_{2}^{**} = & \bigl\vert \sigma _{2}^{p} \bigr\vert \bigl(2p(p-1)\bigr)^{\frac{p}{2}}K_{2}^{**}(p)+[64 \delta ]^{\frac{p}{2}}\bigl[ \vert r_{2}+h_{2} \vert ^{p}K_{2}^{**}(p)+a_{22}^{p}K _{2}^{**}(2p)\bigr] \\ &{}+[64\delta ]^{\frac{p}{2}}a_{23}^{p} \bigl[K_{2}^{**}(2p)+K _{3}^{**}(2p) \bigr]+[64\delta ]^{\frac{p}{2}}a_{21}^{p} \bigl[K_{1}^{**}(2p)+K _{3}^{**}(2p) \bigr] \end{aligned}$$

and

$$\begin{aligned} M_{3}^{**} = & \bigl\vert \sigma _{3}^{p} \bigr\vert \bigl(2p(p-1)\bigr)^{\frac{p}{2}}K_{3}^{**}(p)+[36 \delta ]^{\frac{p}{2}}\bigl[ \vert r_{2}+h_{2} \vert ^{p}K_{3}^{**}(p)+a_{33}^{p}K _{3}^{**}(2p)\bigr] \\ &{}+[36\delta ]^{\frac{p}{2}}a_{32}^{p} \bigl[K_{3}^{**}(2p)+K _{2}^{**}(2p) \bigr]. \end{aligned}$$

From (56)–(58), we obtain that $F_{1}(t)$, $F_{2}(t)$, and $F_{3}(t)$ for $t\in (0,\infty )$ are uniformly continuous. Therefore, from (48) and Barbalat lemma in [25] we can finally obtain (43). This completes the proof. □

Denote by $\mathcal{P}([-\gamma ,0],R_{+}^{3})$ the space of all probability measures on $C([-\gamma ,0],R_{+}^{3})$. For $P_{1},P_{2} \in \mathcal{P}([-\gamma ,0],R_{+}^{3})$, define

$$ d_{\mathrm{BL}}(P_{1},P_{2})=\sup_{f\in \mathrm{BL}} \biggl\vert \int _{R_{+}^{3}}f(z)P_{1}(\mathrm{d}z)- \int _{R_{+}^{3}}f(z)P_{2}(\mathrm{d}z) \biggr\vert , $$

where set BL is defined as follows:

$$ \mathrm{BL}=\bigl\{ f:\mathcal{C}\bigl([-\gamma ,0],R_{+}^{3}\bigr) \rightarrow R: \bigl\vert f(z_{1})-f(z _{2}) \bigr\vert \leq \Vert z_{1}-z_{2} \Vert , \bigl\vert f(\cdot ) \bigr\vert \leq 1\bigr\} . $$

Denote by $p(t,\phi ,\mathrm{d}x)$ the transition probability of process $x(t)=(x_{1}(t),x_{2}(t),x_{3}(t))$. We have the following results.

Theorem 3

Assume that there are positive constants $q_{1}$, $q_{2}$, and $q_{3}$ such that

$$ q_{1}a_{11}-q_{2}a_{21}>0, \qquad q_{2}a_{22}-q_{1}a_{12}-q_{3}a_{32}>0, \qquad q_{3}a_{33}-q_{2}a_{23}>0. $$

Then model (1) is asymptotically stable in distribution, i.e., there exists a unique probability measure $v(\cdot )$ such that, for any initial function $\phi \in C([-\gamma ,0],R_{+}^{3})$, the transition probability $p(t,\phi ,\cdot )$ of $x(t,\phi )=(x_{1}(t,\phi ),x_{2}(t, \phi ),x_{3}(t,\phi ))$ satisfies

$$ \lim_{t\to \infty }d_{\mathrm{BL}}\bigl(p(t,\phi ,\cdot ),v(\cdot ) \bigr)=0. $$

This theorem can be proved using a standard argument as in [15, 16] by using Lemma 1 and Theorem 2. Hence, we here omit it.

4 Effect of harvesting

In model (1), $h_{i}\geq 0$ ($i=1,2,3$) denotes the harvesting rates of species $x_{i}$, respectively. Firstly, based on Theorem 1, we discuss the effects of harvesting for the persistence and extinction of species in model (1).

From $\Delta _{11}=0$, the critical value of harvesting rate $h_{1}$ for prey $x_{1}$ is determined by $h_{1}'=r_{1}-\frac{\sigma _{1}^{2}}{2}$. When $h_{1}\geq h_{1}'$, all species $x_{1}$ ($i=1,2,3$) will die out from conclusions (1) and (2) of Theorem 1. This shows that the excessive harvesting for the prey will lead to the extinction of all species in a food-chain system.

When $h_{1}< h_{1}'$, from $\Delta _{22}=0$, the critical value of harvesting rate $h_{2}$ for middle predator $x_{2}$ is determined by $h_{2}'=\frac{a_{21}}{a_{11}}(r_{1}-\frac{\sigma _{1}^{2}}{2}-h_{1})-(r _{2}+\frac{\sigma ^{2}}{2})$. When $h_{2}\geq h_{2}'$, from conclusions (3) and (4) of Theorem 1 we see that prey $x_{1}$ will be permanent in the mean, but two predators $x_{2}$ and $x_{3}$ will die out. This shows that the excessive harvesting for the middle predator will lead to the extinction of all top species. Furthermore, we see that $h_{2}'$ decreasingly depends on the harvesting rate $h_{1}$ for prey $x_{1}$. This shows that when we increase the harvest for the prey, then the harvest for the middle predator must decrease to just guarantee the non-extinction of the whole food-chain system.

When $h_{2}< h_{2}'$, from $\Delta _{33}=0$, we further obtain that the critical value of harvesting rate $h_{3}$ for top predator $x_{3}$ is

$$ h_{3}'=\frac{[(r_{1}-\frac{\sigma _{1}^{2}}{2}-h_{1})a_{21}-(r_{2}+\frac{ \sigma _{2}^{2}}{2}+h_{2})a_{11}]a_{32}}{H_{2}}-\biggl(r_{3}+ \frac{\sigma _{3}^{2}}{2}\biggr). $$

When $h_{3}\geq h_{3}'$, then from conclusions (5) and (6) of Theorem 1 we see that prey $x_{1}$ and middle predator $x_{2}$ will be permanent in the mean, but top predator $x_{3}$ will die out; whereas when $h_{3}< h_{3}'$, from conclusion (7) of Theorem 1 we see that all species $x_{1}$ ($i=1,2,3$) will be permanent in the mean. This shows that only temperate harvesting for all species can ensure the persistence of all species and a continuous income. Furthermore, we also see that $h_{3}'$ decreasingly depends on the harvesting rates $h_{1}$ and $h_{2}$ for prey and middle predators $x_{1}$ and $x_{2}$. This shows that when there exist the harvests for prey and middle predator, then the harvest for the top predator must decrease; if not, then top predator will die out.

Next, we discuss the optimal harvesting problem under the harvesting rates $h_{1}$, $h_{2}$, and $h_{3}$ for species $x_{1}$, $x_{2}$, and $x_{3}$, respectively. We can establish the following comparatively integrated results.

Theorem 4

Assume that there are positive constants $m_{1}$, $m_{2}$, and $m_{3}$ such that

$$ m_{1}a_{11}-m_{2}a_{21}>0,\qquad m_{2}a_{22}-m_{1}a_{12}-m_{3}a_{32}>0, \qquad m_{3}a_{33}-m_{2}a_{23}>0. $$

Let

$$\begin{aligned}& h_{1}^{*}= \frac{-a_{11}(a_{32}-a_{23})^{2}+2a_{33}a_{21}(a_{12}-a _{21})+4a_{11}a_{22}a_{33}}{2[4a_{11}a_{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a _{11}(a_{23}-a_{32})^{2}]}\biggl(r_{1}-\frac{\sigma _{1}^{2}}{2}\biggr) \\& \hphantom{ h_{1}^{*}=}{}+\frac{a _{11}a_{33}(a_{12}+a_{21})}{4a_{11}a_{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a _{11}(a_{23}-a_{32})^{2}}\biggl(r_{2}+\frac{\sigma _{2}^{2}}{2}\biggr) \\& \hphantom{ h_{1}^{*}=}{}+\frac{a _{11}(a_{12}+a_{21})(a_{32}-a_{23})}{2[4a_{11}a_{22}a_{33}-a_{33}(a _{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}]}\biggl(r_{3}+\frac{\sigma _{3} ^{2}}{2}\biggr), \\& h_{2}^{*}=\biggl\{ \frac{2a_{22}a_{33}(a_{12}+a_{21})}{2[4a _{11}a_{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}]} \\& \hphantom{ h_{2}^{*}=}{}+\frac{(a_{32}-a_{23})(a_{23}a_{12}-a_{32}a_{21})}{2[4a_{11}a_{22}a _{33}-a_{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}]}\biggr\} \biggl(r_{1}-\frac{ \sigma _{1}^{2}}{2} \biggr) \\& \hphantom{ h_{2}^{*}=}{}+\frac{a_{33}a_{12}(a_{12}-a_{21})-a_{11}a_{32}(a _{23}-a_{32})-4a_{11}a_{22}a_{33}}{4a_{11}a_{22}a_{33}-a_{33}(a_{12}-a _{21})^{2}-a_{11}(a_{23}-a_{32})^{2}}\biggl(r_{2}+\frac{\sigma _{2}^{2}}{2}\biggr) \\& \hphantom{ h_{2}^{*}=}{}+\biggl\{ \frac{(a_{12}-a_{21})(a_{21}a_{32}-a_{12}a_{23})}{2[4a_{11}a _{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}]} \\& \hphantom{ h_{2}^{*}=}{}+\frac{2a _{11}a_{22}(a_{23}+a_{32})}{2[4a_{11}a_{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a _{11}(a_{23}-a_{32})^{2}]}\biggr\} \biggl(r_{3}+\frac{\sigma _{3}^{2}}{2}\biggr), \\& h_{3} ^{*}=\frac{a_{33}(a_{21}-a_{12})(a_{23}+a_{32})}{2[4a_{11}a_{22}a _{33}-a_{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}]}\biggl(r_{1}- \frac{ \sigma _{1}^{2}}{2}\biggr) \\& \hphantom{ h_{3}^{*}=}{}-\frac{2a_{11}a_{33}(a_{23}+a_{32})}{4a_{11}a _{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}}\biggl(r _{2}+\frac{\sigma _{2}^{2}}{2}\biggr) \\& \hphantom{ h_{3}^{*}=}{}+\frac{a_{33}(a_{12}-a_{21})^{2}+2a _{11}a_{23}(a_{23}-a_{32})-4a_{11}a_{22}a_{33}}{2[4a_{11}a_{22}a_{33}-a _{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}]}\biggl(r_{3}+\frac{ \sigma _{3}^{2}}{2}\biggr) \end{aligned}$$

(59)

and

$$\begin{aligned} Y^{*}(H) = &-(a_{22}a_{33}+a_{23}a_{32})h_{1}^{2}+(a_{33}a_{12}-a_{33}a _{21})h_{1}h_{2} \\ &{}-a_{11}a_{33}h_{2}^{2}+(a_{11}a_{23}-a_{11}a_{32})h _{2}h_{3}-(a_{11}a_{22}+a_{12}a_{21})h_{3}^{2} \\ &{}-(a_{12}a_{23}+a _{21}a_{32})h_{1}h_{3}+ \biggl[\biggl(r_{1}-\frac{\sigma _{1}^{2}}{2}\biggr) (a_{22}a_{33}+a _{23}a_{32}) \\ &{}+\biggl(r_{2}+\frac{\sigma _{2}^{2}}{2}\biggr)a_{33}a_{12}- \biggl(r_{3}+\frac{ \sigma _{3}^{2}}{2}\biggr)a_{12}a_{23} \biggr]h_{1} \\ &{}+\biggl[\biggl(r_{1}-\frac{\sigma _{1} ^{2}}{2}\biggr)a_{33}a_{21}- \biggl(r_{2}+\frac{\sigma _{2}^{2}}{2}\biggr)a_{11}a_{33} + \biggl(r _{3}+\frac{\sigma _{3}^{2}}{2}\biggr)a_{11}a_{23} \biggr]h_{2} \\ &{}+\biggl[\biggl(r_{1}-\frac{ \sigma _{1}^{2}}{2}\biggr)a_{21}a_{32} -\biggl(r_{2}+\frac{\sigma _{2}^{2}}{2}\biggr)a _{11}a_{32} \\ &{}- \biggl(r_{3}+\frac{\sigma _{3}^{2}}{2}\biggr) (a_{11}a_{22}+a_{12}a_{21}) \biggr]h _{3}. \end{aligned}$$

(60)

We have the following conclusions.

($\mathcal{A}_{1}$):

If $h_{1}^{*}\geq 0$, $h_{2}^{*}\geq 0$, and $h_{3}^{*}\geq 0$, and

$$ \begin{aligned} &\Delta _{33}|_{h_{1}=h_{1}^{*},h_{2}=h_{2}^{*},h_{3}=h_{3}^{*}}>0 , \\ &4a _{11}a_{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}>0. \end{aligned} $$

(61)

Then there is an optimal harvesting strategy $H^{*}=(h_{1}^{*},h_{2} ^{*},h_{3}^{*})$ for model (1), and

$$ MESY=\frac{Y^{*}(H^{*})}{H_{3}}. $$

(62)

($\mathcal{A}_{2}$):

If one of the following conditions holds, then there is not the optimal harvesting strategy for model (1).

($\mathcal{B}_{1}$):

$b_{1}|h_{1}=h_{1}^{*}\leq 0$;

($\mathcal{B}_{2}$):

$\Delta _{33}|_{h_{1}=h_{1}^{*},h_{2}=h_{2}^{*},h _{3}=h_{3}^{*}}\leq 0$;

($\mathcal{B}_{3}$):

$h_{1}^{*}<0$ or $h_{2}^{*}<0$ or $h_{3}^{*}<0$;

($\mathcal{B}_{4}$):

$4a_{11}a_{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a _{11}(a_{23}-a_{32})^{2}<0$.

Proof

Define a set as follows:

$$ \mathcal{U}=\bigl\{ H=(h_{1},h_{2},h_{3})^{T} \in R^{3}:\Delta _{33}>0,h_{i} \geq 0,i=1,2,3\bigr\} . $$

It is clear that for any $H\in \mathcal{U}$ conclusion (7) of Theorem 1 holds. From the condition of conclusion ($\mathcal{A}_{1}$), we see that if optimal harvesting strategy $H^{*}$ exists, then $H^{*}\in \mathcal{U}$.

Proof of conclusion $(\mathcal{A}_{1})$. Based on condition (61) we obtain that $\mathcal{U}$ is not empty. From Theorem 3, we obtain that there exists a unique invariant measure $v(\cdot )$ for model (1). From Corollary 3.4.3 in Prato and Zbczyk [26], we obtain that $v(\cdot )$ is strong mixing. By Theorem 3.2.6 in [26], we further obtain that measure $v(\cdot )$ is also ergodic. Let $x(t)=(x_{1}(t),x_{2}(t),x_{3}(t))$ be any global positive solution of model (1) with initial value $(\xi (\theta ),\eta (\theta ), \varsigma (\theta ))\in C([-\gamma ,0],R_{+}^{3}))$. Based on Theorem 3.3.1 in [26], for $H=(h_{1},h_{2},h_{3})^{T}\in \mathcal{U}$, we have

$$ \lim_{t\rightarrow \infty }\frac{1}{t} \int _{0}^{t}H^{T}x(s)\,\mathrm{d}s= \int _{R_{+}^{3}}H^{T}xv(\mathrm{d}x). $$

(63)

Let $\varrho (z)$ be the stationary probability density of model (1), then we get

$$ Y(H)=\lim_{t\rightarrow \infty }E\Biggl[\sum _{i=1}^{3}h_{i}x_{i}(t)\Biggr]= \lim_{t\rightarrow \infty }E\bigl[H^{T}x(t)\bigr]= \int _{R_{+}^{3}}H^{T}x\varrho (x)\,\mathrm{d}x. $$

(64)

Note that the invariant measure of model (1) is unique and there exists a one-to-one correspondence between $\varrho (z)$ and its corresponding invariant measure. We deduce

$$ \int _{R_{+}^{3}}H^{T}x\varrho (x)\,\mathrm{d}x= \int _{R_{+}^{3}}H^{T}xv(\mathrm{d}x). $$

(65)

Therefore, from conclusion (5) of Theorem 1, (59), and (63)–(65), we have

$$\begin{aligned} Y(H) =&\lim_{t\to +\infty }\frac{1}{t} \int _{0}^{t}H^{T}x(s)\,\mathrm{d}s \\ =&h_{1}\lim_{t\to +\infty }\frac{1}{t} \int _{0}^{t}x_{1}(s)\,\mathrm{d}s+h _{2}\lim_{t\to +\infty }\frac{1}{t} \int _{0}^{t}x_{2}(s)\,\mathrm{d}s +h _{3}\lim_{t\to +\infty }\frac{1}{t} \int _{0}^{t}x_{3}(s)\,\mathrm{d}s \\ =&\frac{Y ^{*}(H)}{H_{3}}. \end{aligned}$$

By calculating we obtain

$$\begin{aligned}& \frac{\partial Y^{*}(H)}{\partial h_{1}} = -2(a_{22}a_{33}+a_{23}a _{32})h_{1}+(a_{33}a_{12}-a_{33}a_{21})h_{2}-(a_{12}a_{23}+a_{21}a _{32})h_{3} \\& \hphantom{\frac{\partial Y^{*}(H)}{\partial h_{1}} =}{}+\biggl(r_{1}-\frac{\sigma _{1}^{2}}{2}\biggr) (a_{22}a_{33}+a_{23}a _{32})+ \biggl(r_{2}+\frac{\sigma _{2}^{2}}{2}\biggr)a_{33}a_{12}- \biggl(r_{3}+\frac{ \sigma _{3}^{2}}{2}\biggr)a_{12}a_{23}, \\& \frac{\partial Y^{*}(H)}{\partial h _{2}} =-2a_{11}a_{33}h_{2}+(a_{33}a_{12}-a_{33}a_{21})h_{1}+(a_{11}a _{23}- a_{11}a_{32})h_{3} \\& \hphantom{\frac{\partial Y^{*}(H)}{\partial h _{2}} =}{}+\biggl(r_{1}-\frac{\sigma _{1}^{2}}{2} \biggr)a_{33}a _{21}-\biggl(r_{2}+\frac{\sigma _{2}^{2}}{2} \biggr)a_{11}a_{33}+\biggl(r_{3}+\frac{\sigma _{3}^{2}}{2} \biggr)a_{11}a_{23} ,\\& \frac{\partial Y^{*}(H)}{\partial h_{3}} = -2(a_{11}a_{22}+a_{12}a _{21})h_{3}+(a_{11}a_{23}-a_{11}a_{32})h_{2}-(a_{12}a_{23}+a_{21}a _{32})h_{1} \\& \hphantom{\frac{\partial Y^{*}(H)}{\partial h_{3}} =}{}+\biggl(r_{1}-\frac{\sigma _{1}^{2}}{2} \biggr)a_{21}a_{32}-\biggl(r_{2}+\frac{ \sigma _{2}^{2}}{2} \biggr)a_{11}a_{32}-\biggl(r_{3}+\frac{\sigma _{3}^{2}}{2} \biggr) (a _{11}a_{22}+a_{12}a_{21}). \end{aligned}$$

Solving equations $\frac{\partial Y^{*}(H)}{\partial h_{1}}=0$, $\frac{\partial Y^{*}(H)}{\partial h_{2}}=0$, and $\frac{\partial Y ^{*}(H)}{\partial h_{3}}=0$, we can obtain $h_{1}=h_{1}^{*}$, $h_{2}=h_{2}^{*}$, and $h_{3}=h_{3}^{*}$, which are given in (59). Let $H^{*}=(h_{1}^{*},h_{2}^{*},h_{3}^{*})$, by calculating we further obtain

$$\begin{aligned} &\frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{1}^{2}} =-2(a_{22}a_{33}+a _{23}a_{32}),\qquad \frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{1}\partial h_{2}} =a_{33}(a_{12}-a_{21}), \\ &\frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{1}\partial h_{3}} =-(a _{12}a_{23}+a_{21}a_{32}),\qquad \frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{2}^{2}} =-2a_{11}a_{33}, \\ &\frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{2}\partial h_{1}} =a _{33}(a_{12}-a_{21}),\qquad \frac{\partial ^{2} Y^{*}(H^{*})}{\partial h _{2}\partial h_{3}} =a_{11}(a_{23}- a_{32}), \\ &\frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{3}^{2}} =-2(a_{11}a_{22}+a _{12}a_{21}),\qquad \frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{3}\partial h_{1}} =-(a_{12}a_{23}+a_{21}a_{32}), \\ &\frac{\partial ^{2} Y^{*}(H^{*})}{\partial h_{3}\partial h_{2}} =a _{11}(a_{23}- a_{32}). \end{aligned}$$

Define matrix $M=(\frac{\partial ^{2}Y^{*}(H^{*})}{\partial h_{i} \partial h_{j}})_{1\leq i,j\leq 3}$. Then condition (61) implies that matrix M is negative definite. We hence obtain that $Y^{*}(H)$ has a unique maximum value $Y^{*}(H^{*})$. This shows that $H^{*}$ is an optimal harvesting strategy, and MESY is given in (62).

Proof of conclusion $(\mathcal{A}_{2})$. From conclusions (1) and (2) of Theorem 1, we can obtain $\lim_{t\to \infty }x_{i}(t)=0$ ($i=1,2,3$) if condition $(\mathcal{B}_{1})$ holds. Hence, the optimal harvesting does not exist.

Assume that condition $(\mathcal{B}_{2})$ or $(\mathcal{B}_{3})$ holds. If there is an optimal harvesting strategy $\widetilde{H}^{*}=( \widetilde{h}_{1}^{*},\widetilde{h}_{2}^{*},\widetilde{h}_{3}^{*})$, then $\widetilde{H}^{*}\in \mathcal{U}$. That is,

$$ \Delta _{33}|_{h_{1}=\widetilde{h}_{1}^{*},h_{2}=\widetilde{h}_{2}^{*},h _{3}=\widetilde{h}_{3}^{*}}>0,\quad \widetilde{h}_{1}^{*}\geq 0, \widetilde{h}_{2}^{*} \geq 0, \widetilde{h}_{3}^{*}\geq 0. $$

(66)

On the other hand, if $\widetilde{H}^{*}=(\widetilde{h}_{1}^{*}, \widetilde{h}_{2}^{*},\widetilde{h}_{3}^{*})\in \mathcal{U}$ is the optimal harvesting strategy, then we also have $(\widetilde{h}_{1} ^{*},\widetilde{h}_{2}^{*},\widetilde{h}_{3}^{*})$ must be the unique solution of the following system:

$$ \frac{\partial Y^{*}(H)}{\partial h_{1}}=0,\qquad \frac{\partial Y^{*}(H)}{ \partial h_{2}}=0,\qquad \frac{\partial Y^{*}(H)}{\partial h_{3}}=0. $$

Therefore, we have $( h_{1}^{*},h_{2}^{*}, h_{3}^{*})=(\widetilde{h} _{1}^{*},\widetilde{h}_{2}^{*},\widetilde{h}_{3}^{*})$. Thus, condition (66) becomes

$$ \Delta _{33}|_{h_{1}= h_{1}^{*},h_{2}= h_{2}^{*},h_{3}= h_{3}^{*}}>0,\quad h_{1}^{*} \geq 0, h_{2}^{*}\geq 0, h_{3}^{*}\geq 0, $$

which contradicts both $(\mathcal{B}_{2})$ and $(\mathcal{B}_{3})$.

Lastly, we consider condition $(\mathcal{B}_{4})$. We can assume that conditions $(\mathcal{B}_{2})$ and $(\mathcal{B}_{3})$ do not hold. Hence, $h_{1}^{*}\geq 0$, $h_{2}^{*}\geq 0$, and $h_{3}^{*}\geq 0$, and $\Delta _{33}|_{h_{1}=h_{1}^{*},h_{2}=h_{2}^{*},h_{3}=h_{3}^{*}}>0$. Thus, $\mathcal{U}$ is not empty. Condition $(\mathcal{B}_{4})$ implies that matrix M is not negative semidefinite. Therefore, there is not any maximum point. This completes the proof. □

5 Numerical examples

In this section, we will provide the numerical examples to illustrate our main results. The numerical approaches are proposed in [13], and also refer to [16]. Firstly, we indicate in the following numerical examples that the initial values always are fixed by $x_{1}(\theta )=0.3e ^{\theta }$, $x_{2}(\theta )=0.2e^{\theta }$, and $x_{3}(\theta )=0.3e ^{\theta }$ for all $\theta \in [-\ln 2,0]$, and $\tau _{12}=\tau _{21}= \tau _{23}=\tau _{32}=\ln 2$.

Example 1

In model (1), parameters $r_{1}=2.0$, $r_{2}=1.0$, $r_{3}=0.5$, and $h_{1}=h_{2}=h_{3}=0$ are fixed. We consider the following cases.

Case 1. Taking parameters $a_{11}=1$, $a_{22}=0.5$, $a_{33}=0.25$, $a_{12}=1$, $a_{21}=1$, $a_{23}=1$, $a_{32}=1$, $\sigma _{1}=2.5$, $\sigma _{2}=0.1$, and $\sigma _{3}=0.05$, we have $\Delta _{11}=-1.125<0$. Hence, the conditions of conclusion (1) in Theorem 1 are satisfied. The numerical simulations given in Fig. 1 illustrate that all species $x_{i}$ ($i=1,2,3$) are extinct with probability one.

Case 2. Taking parameters $a_{11}=1$, $a_{22}=0.5$, $a_{33}=0.25$, $a_{12}=1$, $a_{21}=1$, $a_{23}=1$, $a_{32}=1$, $\sigma _{1}=2.0$, $\sigma _{2}=0.1$, and $\sigma _{3}=0.05$, we have $\Delta _{11}=0$. Hence, the conditions of conclusion (2) in Theorem 1 are satisfied. The numerical simulations given in Fig. 2 illustrate that all species $x_{i}$ ($i=1,2,3$) also are extinct with probability one.

Case 3. Taking parameters $a_{11}=1$, $a_{22}=0.5$, $a_{33}=0.25$, $a_{12}=1$, $a_{21}=0.7$, $a_{23}=1$, $a_{32}=1$, $\sigma _{1}=1.0$, $\sigma _{2}=0.6$, and $\sigma _{3}=0.05$, we have $\Delta _{11}=1.5>0$ and $\Delta _{22}=-0.13<0$. Hence, the conditions of conclusion (3) in Theorem 1 are satisfied. The numerical simulations given in Fig. 3 illustrate that species $x_{1}(t)$ is persistent in the mean while species $x_{i}(t)$ ($i=2,3$) go to extinction.

Case 4. Taking parameters $a_{11}=1$, $a_{22}=0.5$, $a_{33}=0.25$, $a_{12}=1$, $a_{21}=0.78667$, $a_{23}=1$, $a_{32}=1$, $\sigma _{1}=1.0$, $\sigma _{2}=0.5$, and $\sigma _{3}=0.3$, we have $\Delta _{22}=0$. Hence, the conditions of conclusion (4) in Theorem 1 are satisfied. The numerical simulations given in Fig. 4 illustrate that species $x_{1}(t)$ is persistent in the mean, species $x_{2}(t)$ is extinct in the mean and $x_{3}(t)$ is extinct.

Case 5. Taking parameters $a_{11}=1$, $a_{22}=0.5$, $a_{33}=2.5$, $a_{12}=1$, $a_{21}=2$, $a_{23}=1$, $a_{32}=1$, $\sigma _{1}=0.5$, $\sigma _{2}=0.3$, and $\sigma _{3}=1.5$, we have $\Delta _{22}=2.505>0$ and $\Delta _{33}=-1.5575<0$. Hence, the conditions of conclusion (5) in Theorem 1 are satisfied. The numerical simulations given in Fig. 5 illustrate that species $x_{1}(t)$ and $x_{2}(t)$ are persistent in the mean while species $x_{3}(t)$ goes to extinction.

Case 6. Taking parameters $a_{11}=1$, $a_{22}=0.5$, $a_{33}=2.5$, $a_{12}=1$, $a_{21}=2$, $a_{23}=1$, $a_{32}=1$, $\sigma _{1}=0.5$, $\sigma _{2}=0.3$, and $\sigma _{3}=\sqrt{1.004}$, we have $\Delta _{33}=0$. Hence, the conditions of conclusion (6) in Theorem 1 are satisfied. The numerical simulations given in Fig. 6 illustrate that species $x_{1}(t)$ and $x_{2}(t)$ are persistent in the mean while species $x_{3}(t)$ is extinct in the mean.

Case 7. Taking parameters $a_{11}=1$, $a_{22}=0.5$, $a_{33}=1$, $a_{12}=1$, $a_{21}=2$, $a_{23}=1$, $a_{32}=2$, $\sigma _{1}=0.1$, $\sigma _{2}=0.2$, and $\sigma _{3}=0.9$, we have $\Delta _{33}=0.2425>0$. Hence, the conditions of conclusion (7) in Theorem 1 are satisfied. The numerical simulations given in Fig. 7 illustrate that all species $x_{i}(t)$ ($i=1,2,3$) are persistent in the mean.

Example 2

In model (1) we take parameters $r_{1}=1$, $r_{2}=0.3$, $r_{3}=0.1$, $m_{1}=1$, $m_{2}=0.3$, $m_{3}=0.1$, $a_{11}=0.4$, $a_{12}=0.1$, $a_{22}=0.5$, $a_{21}=0.75$, $a_{23}=0.1$, $a_{32}=0.45$, $a_{33}=0.6$, $\sigma _{1}=0.2$, $\sigma _{2}=0.1$, and $\sigma _{3}=\sqrt{0.012}$.

We have $m_{1}a_{11}-m_{2}a_{21}=0.1075>0$, $m_{2}a_{22}-m_{1}a_{12}-m _{3}a_{32}=0.005>0$, and $m_{3}a_{33}-m_{2}a_{23}=0.03>0$. Calculating $h_{i}^{*}$ ($i=1,2,3$) in Theorem 2, we have $h_{1}^{*}=0.0023>0$, $h_{2} ^{*}=0.1414>0$, and $h_{3}^{*}=0.0958>0$. Furthermore, we also have $4a_{11}a_{22}a_{33}-a_{33}(a_{12}-a_{21})^{2}-a_{11}(a_{23}-a_{32})^{2}=0.1175>0$, $\Delta _{33}|_{h_{1}=h_{1}^{*},h_{2}=h_{2}^{*},h_{3}=h_{3}^{*}}=0.4769>0$, and $H_{3}=0.183$. Hence, all conditions of conclusion ($\mathcal{A} _{1}$) in Theorem 2 are satisfied. Hence, there is an optimal harvesting strategy $H^{*}=(0.0023,0.1414,0.0958)^{T}$, and the maximum of expectation of sustainable yield (MESY) is $\frac{Y^{*}(H^{*})}{H_{3}}=0.3464$. The numerical simulations are given in Fig. 8.

6 Conclusion

Ecological and mathematical improvements have provided that three species are more advantageous than two-species models (Pimm [27], Hastings and Powell [28]). Besides, considering the influence of distributed delays and environmental noise, we analyze a stochastic three species food-chain model with harvesting in this paper. By using the stochastic integral inequalities, Lyapunov function method, and the inequality estimation technique, some criteria on the existence of global positive solutions, stochastic boundedness, extinction, global asymptotic stability in the mean and the probability distribution, and the effect of harvesting are established. Our results show some meaningful facts:

(i)
Theorem 1 shows the sufficient and necessary conditions for the extinction and global asymptotic stability in the mean with probability one. In addition, Theorem 1 also reveals the effects of harvesting for the extinction and permanence in the mean of prey, middle predator, and top predator.
(ii)
Theorem 2 and Theorem 3 guarantee the global attractivity in the expectation and the global asymptotic stability in distribution, respectively.
(iii)
Theorem 4 reveals the existence of optimal harvesting strategy and MESY are affected by environmental fluctuations.

There are still some problems waiting for further investigation. Firstly, it is meaningful to study more complex systems, for example, stochastic systems with Lévy jumps (see, for example, [22, 29]), Markovian switching (see, for example, [30]) and nonlinear functional responses (see, for example, [31]), and general stochastic many species food-chain systems. Furthermore, the optimal harvesting problem for other stochastic population systems with distributed delays, for instance, competitive systems and cooperative systems, still are rarely investigated at present. We will leave to investigate these problems in the future.

References

Elton, C.S.: Animal Ecology. Macmillan Co., New York (1927)
Google Scholar
Chiu, C.H., Hsu, S.B.: Extinction of top predator in a three level food-chain model. J. Math. Biol. 37, 372–380 (1998)
Article MathSciNet Google Scholar
Freedman, H., Waltman, P.: Mathematical analysis of some three-species food-chain models. Math. Biosci. 33, 257–276 (1977)
Article MathSciNet Google Scholar
Freedman, H., Waltman, P.: Persistence in models of three interacting predator-prey populations. Math. Biosci. 68, 213–231 (1984)
Article MathSciNet Google Scholar
Hutson, V., Law, R.: Permanent coexistence in general models of three interacting species. J. Math. Biol. 21, 285–298 (1985)
Article MathSciNet Google Scholar
Bao, J., Yuan, C.: Stochastic population dynamics driven by Lévy noise. J. Math. Anal. Appl. 391, 363–375 (2012)
Article MathSciNet Google Scholar
Braumann, C.A.: Itô versus Stratonovich calculus in random population growth. Math. Biosci. 206, 81–107 (2007)
Article MathSciNet Google Scholar
Gard, T.C.: Persistence in stochastic food web models. Bull. Math. Biol. 46, 357–370 (1984)
Article MathSciNet Google Scholar
Liu, M.: Optimal harvesting policy of a stochastic predator-prey model with delay. Appl. Math. Lett. 48, 102–108 (2015)
Article MathSciNet Google Scholar
Jiang, D., Shi, N.: A note on non-autonomous logistic equation with random perturbation. J. Math. Anal. Appl. 303, 164–172 (2005)
Article MathSciNet Google Scholar
Li, Z., Mao, X.: Population dynamical behavior of non-autonomous Lotka–Volterra competitive system with random perturbation. Discrete Contin. Dyn. Syst., Ser. B 24, 523–545 (2009)
Article MathSciNet Google Scholar
Zhu, C., Yin, G.: On competitive Lotka–Volterra model in random environments. J. Math. Anal. Appl. 357, 154–170 (2009)
Article MathSciNet Google Scholar
Liu, M., Bai, C.: Optimal harvesting policy of a stochastic food-chain model with harvesting. Appl. Math. Comput. 245, 265–270 (2014)
MathSciNet MATH Google Scholar
Wei, F., Wang, K.: The existence and uniqueness of the solution for stochastic functional differential equations with infinite dely. J. Math. Anal. Appl. 331, 516–531 (2007)
Article MathSciNet Google Scholar
Wang, S., Wang, L., Wei, T.: Optimal harvesting for a stochastic predator-prey model with s-type distributed time delays. Methodol. Comput. Appl. Probab. 20, 27–68 (2018)
MathSciNet MATH Google Scholar
Liu, M., Bai, C.: Analysis of a stochastic tri-trophic food-chain model with harvesting. J. Math. Biol. 73, 597–625 (2016)
Article MathSciNet Google Scholar
Li, W., Wang, L.: Stability and bifurcation of a delayed three-level food chain model with Beddington–DeAngelis functional response. Nonlinear Anal., Real World Appl. 10, 2471–2477 (2009)
Article MathSciNet Google Scholar
Xu, C., Zhang, Q.: Bifurcation analysis in a predator-prey model with discrete and distributed time delay. Int. J. Appl. Math. Mech. 8(1), 50–65 (2012)
Google Scholar
Ma, Z., Huo, H., Liu, C.: Stability and Hopf bifurcation on a predator-prey model model with discrete and distributed delays. Nonlinear Anal., Real World Appl. 10, 1160–1172 (2009)
Article MathSciNet Google Scholar
Mao, X.: Exponential Stability of Stochastic Differential Equations. Dekker, New York (2007)
MATH Google Scholar
Muhammadhaji, A., Teng, Z., Rehim, M.: On a two species stochastic Lotka–Volterra competition system. J. Dyn. Control Syst. 21, 495–511 (2015)
Article MathSciNet Google Scholar
Liu, M., Wang, K.: Stochastic Lotka–Volterra systems with Lévy noise. J. Math. Anal. Appl. 410, 750–763 (2014)
Article MathSciNet Google Scholar
Bao, J., Yuan, C.: Comparison theorem for stochastic differential delay equations with jumps. Acta Appl. Math. 4, 267–270 (2001)
Google Scholar
Mao, X.: Stochastic Differential Equations and Applications. Horwood, Chichester (2007)
MATH Google Scholar
Barbalat, I.: Systems equations differentielles d’oscillations. Rev. Roum. Math. Pures Appl. 4, 267–270 (1959)
MATH Google Scholar
Prato, G., Zabczyk, J.: Ergodic for Infinite Dimensional Systems. Cambridge University Press, Cambridge (1996)
Book Google Scholar
Pimm, S.L.: Food Webs. Chapman & Hall, New York (1982)
Book Google Scholar
Hastings, A., Powell, T.: Chaos in a three-species food-chain. Ecology 72, 896–903 (1991)
Article Google Scholar
Zeng, T., Teng, Z.: Stability in the mean of a stochastic three species food chain model with general Lévy jumps. Chaos Solitons Fractals 108, 258–265 (2018)
Article Google Scholar
Ge, Y., Xu, Y.: Optimal harvesting policies for a stochastic food-chain system with Markovian switching. Math. Probl. Eng. 2015, 875159 (2015)
MathSciNet MATH Google Scholar
Liu, M.: Dynamics of a stochastic regime-switching predator-prey model with modified Leslie–Gower Holling-type II schemes and prey harvesting. Nonlinear Dyn. (2019). https://doi.org/10.1007/s1107101904797x
Article Google Scholar

Download references

Acknowledgements

We would like to thank the anonymous referees for their helpful comments and the editor for his constructive suggestions, which greatly improved the presentation of this paper.

Availability of data and materials

Data sharing is not applicable to this article as no data sets were generated or analysed during the current study.

Funding

This research is supported by the Natural Science Foundation of China (Grant No. 11771373) and the Natural Science Foundation of Xinjiang Province of China (Grant No. 2016D03022).

Author information

Authors and Affiliations

College of Mathematics and System Sciences, Xinjiang University, Urumqi, People’s Republic of China
Nafeisha Tuerxun, Zhidong Teng & Ahmadjan Muhammadhaji

Authors

Nafeisha Tuerxun
View author publications
You can also search for this author in PubMed Google Scholar
Zhidong Teng
View author publications
You can also search for this author in PubMed Google Scholar
Ahmadjan Muhammadhaji
View author publications
You can also search for this author in PubMed Google Scholar

Contributions

All authors contributed equally to this work. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Zhidong Teng.

Ethics declarations

Competing interests

The authors declare that they have no competing interests.

Additional information

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided 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

Tuerxun, N., Teng, Z. & Muhammadhaji, A. Global dynamics in a stochastic three species food-chain model with harvesting and distributed delays. Adv Differ Equ 2019, 187 (2019). https://doi.org/10.1186/s13662-019-2122-4

Download citation

Received: 18 January 2019
Accepted: 29 April 2019
Published: 15 May 2019
DOI: https://doi.org/10.1186/s13662-019-2122-4

Global dynamics in a stochastic three species food-chain model with harvesting and distributed delays

Abstract

1 Introduction

2 Preliminaries

Lemma 1

Proof

Lemma 2

Lemma 3

Proof

Lemma 4

Lemma 5

Proof

Lemma 6

Proof

3 Global dynamics

Theorem 1

Proof

Theorem 2

Proof

Theorem 3

4 Effect of harvesting

Theorem 4

Proof

5 Numerical examples

Example 1

Example 2

6 Conclusion

References

Acknowledgements

Availability of data and materials

Funding

Author information

Authors and Affiliations

Contributions

Corresponding author

Ethics declarations

Competing interests

Additional information

Publisher’s Note

Rights and permissions

About this article

Cite this article

Share this article

Keywords