Stability of a delayed predator - Prey model in a random environment

Yan Fei Jin; Wen Xian Xie

doi:10.1088/1674-1056/24/11/110501

Stability of a delayed predator - Prey model in a random environment

Yan Fei Jin^*, Wen Xian Xie

^*Corresponding author for this work

School of Aerospace Engineering

Northwestern Polytechnical University Xian

Research output: Contribution to journal › Article › peer-review

7 Citations (Scopus)

Abstract

The stability of the first-order and second-order solution moments for a Harrison-type predator-prey model with parametric Gaussian white noise is analyzed in this paper. The moment equations of the system solution are obtained under Itô interpretations. The delay-independent stable condition of the first-order moment is identical to that of the deterministic delayed system, and the delay-independent stable condition of the second-order moment depends on the noise intensities. The corresponding critical time delays are determined once the stabilities of moments lose. Further, when the time delays are greater than the critical time delays, the system solution becomes unstable with the increase of noise intensities. Finally, some numerical simulations are given to verify the theoretical results.

Original language	English
Article number	110501
Journal	Chinese Physics B
Volume	24
Issue number	11
DOIs	https://doi.org/10.1088/1674-1056/24/11/110501
Publication status	Published - 10 Oct 2015

Keywords

delay-independent stability
environmental noise
moment equations
predator-prey model

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10.1088/1674-1056/24/11/110501

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title = "Stability of a delayed predator - Prey model in a random environment",

abstract = "The stability of the first-order and second-order solution moments for a Harrison-type predator-prey model with parametric Gaussian white noise is analyzed in this paper. The moment equations of the system solution are obtained under It{\^o} interpretations. The delay-independent stable condition of the first-order moment is identical to that of the deterministic delayed system, and the delay-independent stable condition of the second-order moment depends on the noise intensities. The corresponding critical time delays are determined once the stabilities of moments lose. Further, when the time delays are greater than the critical time delays, the system solution becomes unstable with the increase of noise intensities. Finally, some numerical simulations are given to verify the theoretical results.",

keywords = "delay-independent stability, environmental noise, moment equations, predator-prey model",

author = "Jin, {Yan Fei} and Xie, {Wen Xian}",

note = "Publisher Copyright: {\textcopyright} 2015 Chinese Physical Society and IOP Publishing Ltd.",

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AU - Jin, Yan Fei

AU - Xie, Wen Xian

PY - 2015/10/10

Y1 - 2015/10/10

N2 - The stability of the first-order and second-order solution moments for a Harrison-type predator-prey model with parametric Gaussian white noise is analyzed in this paper. The moment equations of the system solution are obtained under Itô interpretations. The delay-independent stable condition of the first-order moment is identical to that of the deterministic delayed system, and the delay-independent stable condition of the second-order moment depends on the noise intensities. The corresponding critical time delays are determined once the stabilities of moments lose. Further, when the time delays are greater than the critical time delays, the system solution becomes unstable with the increase of noise intensities. Finally, some numerical simulations are given to verify the theoretical results.

AB - The stability of the first-order and second-order solution moments for a Harrison-type predator-prey model with parametric Gaussian white noise is analyzed in this paper. The moment equations of the system solution are obtained under Itô interpretations. The delay-independent stable condition of the first-order moment is identical to that of the deterministic delayed system, and the delay-independent stable condition of the second-order moment depends on the noise intensities. The corresponding critical time delays are determined once the stabilities of moments lose. Further, when the time delays are greater than the critical time delays, the system solution becomes unstable with the increase of noise intensities. Finally, some numerical simulations are given to verify the theoretical results.

KW - delay-independent stability

KW - environmental noise

KW - moment equations

KW - predator-prey model

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Stability of a delayed predator - Prey model in a random environment

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