Analysis of linear determinacy for spread in cooperative models

Hans F. Weinberger; Mark A. Lewis; Bingtuan Li

doi:10.1007/s002850200145

Analysis of linear determinacy for spread in cooperative models

Hans F. Weinberger, Mark A. Lewis, Bingtuan Li

School of Mathematics

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

321 Scopus citations

Abstract

The discrete-time recursion system u_n+1 = Q[u_n] with u_n(x) a vector of population distributions of species and Q an operator which models the growth, interaction, and migration of the species is considered. Previously known results are extended so that one can treat the local invasion of an equilibrium of cooperating species by a new species or mutant. It is found that, in general, the resulting change in the equilibrium density of each species spreads at its own asymptotic speed, with the speed of the invader the slowest of the speeds. Conditions on Q are given which insure that all species spread at the same asymptotic speed, and that this speed agrees with the more easily calculated speed of a linearized problem for the invader alone. If this is true we say that the recursion has a single speed and is linearly determinate. The conditions are such that they can be verified for a class of reaction-diffusion models.

Original language	English (US)
Pages (from-to)	183-218
Number of pages	36
Journal	Journal of Mathematical Biology
Volume	45
Issue number	3
DOIs	https://doi.org/10.1007/s002850200145
State	Published - Sep 2002

Keywords

Cooperative model
Discrete-time model
Linear conjecture
Linear determinacy
Reaction-diffusion
Spreading speed

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10.1007/s002850200145

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title = "Analysis of linear determinacy for spread in cooperative models",

abstract = "The discrete-time recursion system un+1 = Q[un] with un(x) a vector of population distributions of species and Q an operator which models the growth, interaction, and migration of the species is considered. Previously known results are extended so that one can treat the local invasion of an equilibrium of cooperating species by a new species or mutant. It is found that, in general, the resulting change in the equilibrium density of each species spreads at its own asymptotic speed, with the speed of the invader the slowest of the speeds. Conditions on Q are given which insure that all species spread at the same asymptotic speed, and that this speed agrees with the more easily calculated speed of a linearized problem for the invader alone. If this is true we say that the recursion has a single speed and is linearly determinate. The conditions are such that they can be verified for a class of reaction-diffusion models.",

keywords = "Cooperative model, Discrete-time model, Linear conjecture, Linear determinacy, Reaction-diffusion, Spreading speed",

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AU - Weinberger, Hans F.

AU - Lewis, Mark A.

AU - Li, Bingtuan

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N2 - The discrete-time recursion system un+1 = Q[un] with un(x) a vector of population distributions of species and Q an operator which models the growth, interaction, and migration of the species is considered. Previously known results are extended so that one can treat the local invasion of an equilibrium of cooperating species by a new species or mutant. It is found that, in general, the resulting change in the equilibrium density of each species spreads at its own asymptotic speed, with the speed of the invader the slowest of the speeds. Conditions on Q are given which insure that all species spread at the same asymptotic speed, and that this speed agrees with the more easily calculated speed of a linearized problem for the invader alone. If this is true we say that the recursion has a single speed and is linearly determinate. The conditions are such that they can be verified for a class of reaction-diffusion models.

AB - The discrete-time recursion system un+1 = Q[un] with un(x) a vector of population distributions of species and Q an operator which models the growth, interaction, and migration of the species is considered. Previously known results are extended so that one can treat the local invasion of an equilibrium of cooperating species by a new species or mutant. It is found that, in general, the resulting change in the equilibrium density of each species spreads at its own asymptotic speed, with the speed of the invader the slowest of the speeds. Conditions on Q are given which insure that all species spread at the same asymptotic speed, and that this speed agrees with the more easily calculated speed of a linearized problem for the invader alone. If this is true we say that the recursion has a single speed and is linearly determinate. The conditions are such that they can be verified for a class of reaction-diffusion models.

KW - Cooperative model

KW - Discrete-time model

KW - Linear conjecture

KW - Linear determinacy

KW - Reaction-diffusion

KW - Spreading speed

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Analysis of linear determinacy for spread in cooperative models

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