Stochastic Nicholson s blowflies delay differential equation with regime switching

Similar documents
Applied Mathematics Letters. Stationary distribution, ergodicity and extinction of a stochastic generalized logistic system

Stationary distribution and pathwise estimation of n-species mutualism system with stochastic perturbation

Asymptotic behaviour of the stochastic Lotka Volterra model

Research Article Existence and Uniqueness Theorem for Stochastic Differential Equations with Self-Exciting Switching

Stability of Stochastic Differential Equations

Theoretical Tutorial Session 2

DYNAMICS OF LOGISTIC SYSTEMS DRIVEN BY LÉVY NOISE UNDER REGIME SWITCHING

On a non-autonomous stochastic Lotka-Volterra competitive system

(2014) A 51 (1) ISSN

An adaptive numerical scheme for fractional differential equations with explosions

Some Properties of NSFDEs

ON SOME CONSTANTS FOR OSCILLATION AND STABILITY OF DELAY EQUATIONS

Impulsive Stabilization of certain Delay Differential Equations with Piecewise Constant Argument

Chapter 2 Event-Triggered Sampling

Delay-dependent Stability Analysis for Markovian Jump Systems with Interval Time-varying-delays

Bernardo D Auria Stochastic Processes /10. Notes. Abril 13 th, 2010

Solution of Stochastic Optimal Control Problems and Financial Applications

Mean-square Stability Analysis of an Extended Euler-Maruyama Method for a System of Stochastic Differential Equations

arxiv: v1 [math.pr] 20 May 2018

Existence of homoclinic solutions for Duffing type differential equation with deviating argument

A numerical method for solving uncertain differential equations

p 1 ( Y p dp) 1/p ( X p dp) 1 1 p

The multidimensional Ito Integral and the multidimensional Ito Formula. Eric Mu ller June 1, 2015 Seminar on Stochastic Geometry and its applications

Squared Bessel Process with Delay

UNCERTAINTY FUNCTIONAL DIFFERENTIAL EQUATIONS FOR FINANCE

Stochastic Differential Equations.

Impulsive stabilization of two kinds of second-order linear delay differential equations

Bernardo D Auria Stochastic Processes /12. Notes. March 29 th, 2012

The LaSalle Stability Theorem of General Stochastic Hybrid Systems

PROBABILITY: LIMIT THEOREMS II, SPRING HOMEWORK PROBLEMS

Partial Differential Equations with Applications to Finance Seminar 1: Proving and applying Dynkin s formula

Path integrals for classical Markov processes

Order-Preservation for Multidimensional Stochastic Functional Differential Equations with Jump

Non-zero Sum Stochastic Differential Games of Fully Coupled Forward-Backward Stochastic Systems

EULER MARUYAMA APPROXIMATION FOR SDES WITH JUMPS AND NON-LIPSCHITZ COEFFICIENTS

PROBABILITY: LIMIT THEOREMS II, SPRING HOMEWORK PROBLEMS

MASSACHUSETTS INSTITUTE OF TECHNOLOGY 6.265/15.070J Fall 2013 Lecture 22 12/09/2013. Skorokhod Mapping Theorem. Reflected Brownian Motion

A Stochastic Viral Infection Model with General Functional Response

Birth and Death Processes. Birth and Death Processes. Linear Growth with Immigration. Limiting Behaviour for Birth and Death Processes

Time-delay feedback control in a delayed dynamical chaos system and its applications

Reflected Brownian Motion

Exercises. T 2T. e ita φ(t)dt.

BIOCOMP 11 Stability Analysis of Hybrid Stochastic Gene Regulatory Networks

EXTINCTION TIMES FOR A GENERAL BIRTH, DEATH AND CATASTROPHE PROCESS

Generalized Riccati Equations Arising in Stochastic Games

The concentration of a drug in blood. Exponential decay. Different realizations. Exponential decay with noise. dc(t) dt.

Verona Course April Lecture 1. Review of probability

Stability Analysis And Maximum Profit Of Logistic Population Model With Time Delay And Constant Effort Of Harvesting

A Barrier Version of the Russian Option

SDE Coefficients. March 4, 2008

Stochastic Viral Dynamics with Beddington-DeAngelis Functional Response

Optimal harvesting policy of a stochastic delay predator-prey model with Lévy jumps

A Concise Course on Stochastic Partial Differential Equations

SMSTC (2007/08) Probability.

On Lyapunov stability of scalar stochastic time-delayed systems

POSITIVE SOLUTIONS FOR BOUNDARY VALUE PROBLEM OF SINGULAR FRACTIONAL FUNCTIONAL DIFFERENTIAL EQUATION

Nested Uncertain Differential Equations and Its Application to Multi-factor Term Structure Model

OBSTACLE PROBLEMS FOR NONLOCAL OPERATORS: A BRIEF OVERVIEW

Research Article Stabilization Analysis and Synthesis of Discrete-Time Descriptor Markov Jump Systems with Partially Unknown Transition Probabilities

ITÔ S ONE POINT EXTENSIONS OF MARKOV PROCESSES. Masatoshi Fukushima

ASYMPTOTIC STABILITY IN THE DISTRIBUTION OF NONLINEAR STOCHASTIC SYSTEMS WITH SEMI-MARKOVIAN SWITCHING

Session 1: Probability and Markov chains

Research Article Reliability Analysis of Wireless Sensor Networks Using Markovian Model

Asymptotic behavior of sample paths for retarded stochastic differential equations without dissipativity

Lecture 4: Introduction to stochastic processes and stochastic calculus

Limiting behaviour of moving average processes under ρ-mixing assumption

A random perturbation approach to some stochastic approximation algorithms in optimization.

MA8109 Stochastic Processes in Systems Theory Autumn 2013

Multi-dimensional Stochastic Singular Control Via Dynkin Game and Dirichlet Form

Introduction Optimality and Asset Pricing

Massachusetts Institute of Technology

Dynamics of delay differential equations with distributed delays

Simulation methods for stochastic models in chemistry

Robust Control of Uncertain Stochastic Recurrent Neural Networks with Time-varying Delay

Runge-Kutta Method for Solving Uncertain Differential Equations

Stochastic Differential Equations in Population Dynamics

Finite-time Ruin Probability of Renewal Model with Risky Investment and Subexponential Claims

1 Brownian Local Time

EXISTENCE AND GLOBAL ATTRACTIVITY OF PERIODIC SOLUTION OF A MODEL IN POPULATION DYNAMICS

Random Locations of Periodic Stationary Processes

Exponential stability for a stochastic delay neural network with impulses

On pathwise stochastic integration

Predicting the Time of the Ultimate Maximum for Brownian Motion with Drift

Irregular Birth-Death process: stationarity and quasi-stationarity

ON THE GLOBAL ATTRACTOR OF DELAY DIFFERENTIAL EQUATIONS WITH UNIMODAL FEEDBACK. Eduardo Liz. Gergely Röst. (Communicated by Jianhong Wu)

Stochastic Integration and Stochastic Differential Equations: a gentle introduction

A DELAY-DEPENDENT APPROACH TO DESIGN STATE ESTIMATOR FOR DISCRETE STOCHASTIC RECURRENT NEURAL NETWORK WITH INTERVAL TIME-VARYING DELAYS

lim n C1/n n := ρ. [f(y) f(x)], y x =1 [f(x) f(y)] [g(x) g(y)]. (x,y) E A E(f, f),

An Uncertain Control Model with Application to. Production-Inventory System

OPTIMAL STOPPING OF A BROWNIAN BRIDGE

Nonlinear representation, backward SDEs, and application to the Principal-Agent problem

Solution for Problem 7.1. We argue by contradiction. If the limit were not infinite, then since τ M (ω) is nondecreasing we would have

A stochastic particle system for the Burgers equation.

Kai Lai Chung

Applied Mathematics Letters

EXAMINATIONS OF THE ROYAL STATISTICAL SOCIETY

Central limit theorems for ergodic continuous-time Markov chains with applications to single birth processes

Recurrence and Ergodicity for A Class of Regime-Switching Jump Diffusions

THE VALUE FUNCTION IN ERGODIC CONTROL OF DIFFUSION PROCESSES WITH PARTIAL OBSERVATIONS II

DISSIPATIVITY OF NEURAL NETWORKS WITH CONTINUOUSLY DISTRIBUTED DELAYS

Transcription:

arxiv:191.385v1 [math.pr 12 Jan 219 Stochastic Nicholson s blowflies delay differential equation with regime switching Yanling Zhu, Yong Ren, Kai Wang,, Yingdong Zhuang School of Statistics and Applied Mathematics, Anhui University of Finance and Economics, Bengbu 2333, Anhui, China Department of Mathematics, Anhui Normal University Wuhu 241, Anhui, China Abstract In this paper, we investigate the global existence of almost surely positive solution to a stochastic Nicholson s blowflies delay differential equation with regime switching, and give the estimation of the path. The results presented in this paper extend some corresponding results in Wang et al. stochastic Nicholson s blowflies delayed differential equations, Appl. Math. Lett. 87 (219) 2-26. Keywords Nicholson s blowflies model, Regime switching, Global solution AMS(2) 34K5; 6H1; 65C3 1 Introduction Gurney et al. (199) [1 proposed the following delay differential equation (known as the famous Nicholson s blowflies model), X (t) = δx(t)+px(t τ)e ax(t τ), (1.1) to model the population of the Australian sheep-blowfly(lucilia cuprina), where p is the maximum per capita daily egg production rate, 1/a is the size at which the blowfly population reproduces at its maximum rate, δ is the per capita daily adult death rate, and τ is the generation time. After that, the dynamics of this equation was studied by Supported by the NSF of China(1187176,71831),the NSF of Anhui Province(17885MA17),the NSF of Education Bureau of Anhui Province(KJ218A437). Corresponding author. e-mail: zhyanling99@126.com(y. Zhu), brightry@hotmail.com(y. Ren), wangkai5318@ 163.com(K. Wang) 1

many researchers, see Berezansky et al. (21) [2 for an overview of the results on the classical Nicholson s model. Considering that the parameter δ is affected by environmental noises, with δ δ σdb(t), where B(t) is a one-dimensional Brownian motion with B() = defined on a complete probability space (Ω,{F t } t,p), σ denotes the intensity of the noise. Wang et al. (219)[3 presented the following stochastic Nicholson s blowflies delay differential equation dx(t) = [ δx(t)+px(t τ)e ax(t τ) dt+σx(t)db(t), (1.2) with initial conditions X(s) = φ(s), for s [ τ,,φ C([ τ,,[,+ )),φ() >. Under the condition δ > σ 2 /2, they prove that Eq.(1.2) has a unique global solution on [ τ, ), which is positive a.s. on [, ), and give the estimation of limsup t E[X(t) 1 and limsup E[ t X(s)ds, respectively. t But we find from numerical simulation that the condition δ > σ 2 /2 is too strict to the nonexplosion of the solution to equation (1.2). For example, let δ = 1, p = 5, τ = 1, a = 1, σ = 2, and the numerical simulation is showing in figure 1. One can see from figure 1 that the solution X(t) is globally existent on [,+ ), and oscillatory about N = logp/δ, which is the positive equilibrium of the corresponding deterministic equation of equation (1.2), but δ < σ 2 /2. 4 35 X()=1 N*=log p/δ 1.694 3 X(t) 25 2 15 1 5 5 1 15 2 Time t Figure 1. The numerical solution X(t) of equation (1.2) with initial value φ(t) = 1 for t [ 1, and the step = 1e 4. On the other hand, as we know that besides the white noise there is another type of environmental noise in the real ecosystem, that is the telegraph noise, which can be demonstrated as a switching between two or more regimes of environment. The regime switching can be modeled by a continuous time Markov chain (r t ) t taking values in a 2

finite state spaces S = {1,2,...,m} and with infinitesimal generator Q = (q ij ) R m m. That is r t satisfies { q ij +o( ), for i j, P(r t+ = j r t = i) = as +, 1+q ij +o( ), for i = j, where q ij is the transition rate from i to j for i j, and q ii = i j q ij for each i S, see Mao et al. (26) [4, Khasminskii et al. (27) [5 and Yin et al. (29) [6 for more details. We assume that the Markov chain r t is independent of the Brownian motion B(t). Considering both the effects of white noise and telegraph noise of environment, we present the following stochastic Nicholson s blowflies delay differential equation with regime switching dx(t) = [ δ rt X(t)+p rt X(t τ rt )e ar t X(t τr t ) dt+σ rt X(t)dB(t) (1.3) with initial conditions X(s) = φ(s), for s [ τ,,φ C([ τ,,r + ), (1.4) where τ = max rt S{τ rt }, R + = [,+ ). The contribution of this paper is as follows, The equation (1.3) considered in this paper includes regime switching, which is more general than equation (1.2); We show the global existence of almost surely positive solution to equation (1.3) without condition δ i > σi 2 /2, i S, which extends the one in [3; We give the estimation of limsup t E[X θ 1 (t) and limsup E[ t t Xθ (s)ds for θ [1,1+2min i S {δ i /σ i }, which is more general than the ones in literature. 2 Main Results In this section, we will show the global existence of almost surely solution of equation (1.3) with initial value (1.4), and give the estimation of the solution. For simplicity, in the following we use the notations: β i = θ[δ i + 1 2 (1 θ)σ2 i, γ i = θp i /(a i e), ρ = min i S {δ i/σ 2 i},m 1 = max i S,x R +{γ ix θ 1 β i x θ }, M 2 = max i S,x R +{(α β i)x θ +γ i x θ 1 }, and < α < min i S β i. Theorem 2.1. For any given initial value (1.4) with φ() >, equation (1.3) has a unique solution X(t) on [ τ, ), which is positive on [, ) a.s.; furthermore, for θ [1,1+2ρ), the solution X(t) of equation (1.3) has the properties: [ lim supe[x θ 1 t (t) M 1, and limsup t t t E X θ (s)ds M 2 /α. 3

Proof. Since all the coefficients of equation (1.3) are locally Lipschitz continuous on R +, then for any given initial value (1.4) with φ() >, there is a unique maximal local solution X(t) on t [ τ,λ e ), where Λ e is the explosion time. Step 1. We first show that X(t) is positive almost surely on [,Λ e ). For r t = i S, and t [,τ i, the initial problem (1.3)-(1.4) with φ() > reduces to the following linear stochastic differential equation, dx(t) =[ δ i X(t)+f i1 (t)dt+σ i X(t)dB(t), (2.5) where f i1 (t) = p i X(t τ i )e a ix(t τ i ) on t [,τ i. The solution of equation (2.5) is [ X(t) = e (δ i+σi 2/2)t+σ ib(t) φ()+ e (δ i+σi 2/2)s σ ib(s) f i1 (s)ds > a.s.,t [,τ i, and for t [τ i,2τ i, equation (1.3) reduces to the following initial problem, dx(t) =[ δ i X(t)+f i2 (t)dt+σ i X(t)dB(t), with X(τ i ) > a.s. (2.6) where f i2 (t) = p i X(t τ i )e a ix(t τ i ) > a.s. on t [τ i,2τ i. The solution of equation (2.6) is [ X(t) = e (δ i+σi 2/2)t+σ ib(t) (δi+σ2 X(τ i )+ e i /2)s σib(s) f i2 (s)ds > a.s.,t [τ i,2τ i, τ i Repeating this procedure, we can obtain that X(t) > a.s. on [,Λ e ). Step 2. Now, we prove that this solution X(t) to equation (1.3) is global existence, that is, the solution will not explode in finite time. We only need to show Λ e = a.s. Let k > be sufficiently large that max t [ τ, φ(t) < k, and for each integer k k define the stopping time Λ k = inf{t [,Λ e ) X(t) k)}. It is clear that Λ k is increasing as k. Let Λ = lim k Λ k, whence Λ Λ e a.s. In order to show Λ e =, we only need to prove that Λ = a.s. If it is false, then there is a pair of constants T > and ǫ (,1) such that P{Λ T} > ǫ, which yields that there exists an integer k 1 k such that P{Λ k T} ǫ for all k k 1. Let V(x,i) = x θ with θ [1,1+2ρ), then V x = θxθ 1, 2 V x 2 = θ(θ 1)x θ 2 and by Itô s formula we have dv(x(t)) =[ β i X θ (t)+θp i X θ 1 (t)x(t τ i )e a ix(t τ i ) dt+θσ i X θ (t)db(t) LV(X(t),i)dt+θσ i X θ db(t) (2.7) It follows from X(t) > a.s. on [,Λ e ) and β i > for all i S that there exists a positive constant M 1 such that LV(X(t),i) β i X θ (t)+γ i X θ 1 (t) M 1. 4

Thus, we have dv(x(t)) M 1 dt+θσ i X θ (t)db(t), For t [,τ i, integrating both sides of above inequality on [,Λ n t and taking expectation give then Λn t dv(x(t)) Λn t M 1 dt+ Λn t θσ i X θ (s)db(s), EV(Λ n t) V(φ())+ME(Λ n t) V(φ())+Mτ i, which yields Λ τ i a.s.. Repeating this procedure, we can obtain that Λ mτ i a.s. for any positive integer m, which implies Λ = a.s.. Step 3. Lastly, we give the estimation of the solution X(t). It follows from Itô formula that E[e t V(X(t)) V(φ())+ which yields limsup t E[V(X(t)) M 1. It follows from equation (2.7) that dv(t)+αx θ (t)dt M 2 dt+θσ i X θ (s)db(s) Integrating above inequality from to t gives dv(t)+α X θ (s)ds M 1 e s ds = V(φ())+M 1 (e t 1), M 2 dt+ Taking expectation on both sides of it gives [ αe X θ (s)ds M 2 t+v(φ()), which gives limsup t 1 t E[ Xθ (s)ds M 2 α. 3 Example θσ i X θ (s)db(s) In this section we will give an example to check the results obtained in section 2 by numerical simulation. Let S = {1,2,3}, Q = [ 1,4,6;2, 3,1;3,5, 8, δ = [2,1,4, p = [4,2,8, τ = [1,1,1, a = [.4,.2,.3, σ = [1.5,2,3, and φ(t) = 1, t [ 1,, then the unique stationary distribution of Markov chain r t is π = (.1845,.619,.2136) and one can see that δ 1 > σ 2 1/2, δ 2 = σ 2 2/2, and δ 3 < σ 2 3/2. It follows from Theorem 2.1 that the solution of equation (1.3) is global existence and positive almost surely on R +, see numerical simulation in figure 2 for details. Meanwhile, we see that ρ =.25, M 1.8829 for θ = 1, and M 2.3713 for θ = 1.4, then limsup t E[X(t).8829 and limsup t E[X 7/5 (t).3713. 5

6 r =3 r 4 t 2 X(t).5 1 1.5 2 Time t x 1 5 2 15 1 5 φ()=1 N*=log p/δ.6931 limsup t E[X(t).8829 5 1 15 2 Time t Figure 2. The numerical simulation of the processes (X(t),r t ) with initial value φ(t) = 1 for t [ 1, and the step = 1e 4. 4 Conclusion In this paper, we consider a stochastic Nicholson s blowflies delay differential equation with regime switching. To the best of our knowledge it is the first time that regime switching is considered in Nicholson s blowflies model. By choosing suitable V function we prove that the solution of the stochastic Nicholson s blowflies model is globally existent, which is also positive almost surely on R +. The results presented in this paper extend some corresponding results in literature. There are still some interesting problems of equation (1.3): 1) Find conditions for the extinction of the species, that is lim t X(t) = ; 2) Find conditions for the weak persistent of the species, that is limsup t X(t) >. References [1 W.S.C. Gurney, S.P. Blythe, R.M. Nisbet, Nicholsons blowflies revisited, Nature 287 (198) 17-21. [2 L. Berezansky, E. Braverman, L. Idels, Nicholsons blowflies differential equations revisited: Main results and open problems, Appl. Math. Model. 34 (21) 145-1417. [3 W.T. Wang, L.Q. Wang, W. Chen, Stochastic Nicholsons blowflies delayed differential equations, Appli. Math. Lett. 87 (219) 2-26. [4 X. Mao, C. Yuan, Stochastic differential equations with Markovian switching. Imperial College Press, 26. [5 R.Z. Khasminskii, C. Zhu, G. Yin, Stability of regime-switching diffusions. Stoch. Process Appl. 117 (27) 137-151. [6 G.G. Yin, C. Zhu, Hybrid Switching Diffusions, Properties and Applications, Springer New York, 29. 6

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback