PERMANENCE AND UNIVERSAL CLASSIFICATION OF DISCRETE-TIME COMPETITIVE SYSTEMS VIA THE CARRYING SIMPLEX

Mats Gyllenberg; Jifa Jiang; Lei Niu; Ping Yan

doi:10.3934/dcds.2020088

PERMANENCE AND UNIVERSAL CLASSIFICATION OF DISCRETE-TIME COMPETITIVE SYSTEMS VIA THE CARRYING SIMPLEX

Mats Gyllenberg, Jifa Jiang, Lei Niu, Ping Yan

Department of Mathematics and Statistics

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

Original language	English
Journal	Discrete and continuous dynamical systems
Volume	40
Issue number	3
Pages (from-to)	1621-1663
Number of pages	43
ISSN	1078-0947
DOIs	https://doi.org/10.3934/dcds.2020088
Publication status	Published - Mar 2020
MoE publication type	A1 Journal article-refereed

Bibliographical note

We study the permanence and impermanence for discrete-time Kolmogorov systems admitting a carrying simplex. Sufficient conditions to guarantee permanence and impermanence are provided based on the existence of a carrying simplex. Particularly, for low-dimensional systems, permanence and impermanence can be determined by boundary fixed points. For a class of competitive systems whose fixed points are determined by linear equations, there always exists a carrying simplex. We provide a universal classification via the equivalence relation relative to local dynamics of boundary fixed points for the three-dimensional systems by the index formula on the carrying simplex. There are a total of 33 stable equivalence classes which are described in terms of inequalities on parameters, and we present the phase portraits on their carrying simplices. Moreover, every orbit converges to some fixed point in classes 1-25 and 33; there is always a heteroclinic cycle in class 27; Neimark-Sacker bifurcations may occur in classes 26-31 but cannot occur in class 32. Based on our permanence criteria and the equivalence classification, we obtain the specific conditions on parameters for permanence and impermanence. Only systems in classes 29,31,33 and those in class 27 with a repelling heteroclinic cycle are permanent. Applications to discrete population models including the Leslie-Gower models, Atkinson-Allen models and Ricker models are given.

Fields of Science

111 Mathematics
Permanence
population model
Neimark-Sacker bifurcation
heteroclinic cycle
phase portrait
fixed point index
classification
competitive system
carrying simplex

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10.3934/dcds.2020088

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Cite this

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title = "PERMANENCE AND UNIVERSAL CLASSIFICATION OF DISCRETE-TIME COMPETITIVE SYSTEMS VIA THE CARRYING SIMPLEX",

keywords = "111 Mathematics, Permanence, population model, Neimark-Sacker bifurcation, heteroclinic cycle, phase portrait, fixed point index, classification, competitive system, carrying simplex",

author = "Mats Gyllenberg and Jifa Jiang and Lei Niu and Ping Yan",

note = "We study the permanence and impermanence for discrete-time Kolmogorov systems admitting a carrying simplex. Sufficient conditions to guarantee permanence and impermanence are provided based on the existence of a carrying simplex. Particularly, for low-dimensional systems, permanence and impermanence can be determined by boundary fixed points. For a class of competitive systems whose fixed points are determined by linear equations, there always exists a carrying simplex. We provide a universal classification via the equivalence relation relative to local dynamics of boundary fixed points for the three-dimensional systems by the index formula on the carrying simplex. There are a total of 33 stable equivalence classes which are described in terms of inequalities on parameters, and we present the phase portraits on their carrying simplices. Moreover, every orbit converges to some fixed point in classes 1-25 and 33; there is always a heteroclinic cycle in class 27; Neimark-Sacker bifurcations may occur in classes 26-31 but cannot occur in class 32. Based on our permanence criteria and the equivalence classification, we obtain the specific conditions on parameters for permanence and impermanence. Only systems in classes 29,31,33 and those in class 27 with a repelling heteroclinic cycle are permanent. Applications to discrete population models including the Leslie-Gower models, Atkinson-Allen models and Ricker models are given.",

year = "2020",

month = mar,

doi = "10.3934/dcds.2020088",

language = "English",

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issn = "1078-0947",

publisher = "American Institute of Mathematical Sciences",

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T1 - PERMANENCE AND UNIVERSAL CLASSIFICATION OF DISCRETE-TIME COMPETITIVE SYSTEMS VIA THE CARRYING SIMPLEX

AU - Gyllenberg, Mats

AU - Jiang, Jifa

AU - Niu, Lei

AU - Yan, Ping

N1 - We study the permanence and impermanence for discrete-time Kolmogorov systems admitting a carrying simplex. Sufficient conditions to guarantee permanence and impermanence are provided based on the existence of a carrying simplex. Particularly, for low-dimensional systems, permanence and impermanence can be determined by boundary fixed points. For a class of competitive systems whose fixed points are determined by linear equations, there always exists a carrying simplex. We provide a universal classification via the equivalence relation relative to local dynamics of boundary fixed points for the three-dimensional systems by the index formula on the carrying simplex. There are a total of 33 stable equivalence classes which are described in terms of inequalities on parameters, and we present the phase portraits on their carrying simplices. Moreover, every orbit converges to some fixed point in classes 1-25 and 33; there is always a heteroclinic cycle in class 27; Neimark-Sacker bifurcations may occur in classes 26-31 but cannot occur in class 32. Based on our permanence criteria and the equivalence classification, we obtain the specific conditions on parameters for permanence and impermanence. Only systems in classes 29,31,33 and those in class 27 with a repelling heteroclinic cycle are permanent. Applications to discrete population models including the Leslie-Gower models, Atkinson-Allen models and Ricker models are given.

PY - 2020/3

Y1 - 2020/3

KW - 111 Mathematics

KW - Permanence

KW - population model

KW - Neimark-Sacker bifurcation

KW - heteroclinic cycle

KW - phase portrait

KW - fixed point index

KW - classification

KW - competitive system

KW - carrying simplex

U2 - 10.3934/dcds.2020088

DO - 10.3934/dcds.2020088

M3 - Article

SN - 1078-0947

VL - 40

SP - 1621

EP - 1663

JO - Discrete and continuous dynamical systems

JF - Discrete and continuous dynamical systems

IS - 3

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