Discrete Lotka–Volterra systems with time delay and its stability analysis

Yusaku Yamamoto; Taisei Yamamoto; Takumi Kuroiwa; Kurumi Oka; Emiko Ishiwata; Masashi Iwasaki

doi:10.1016/j.physd.2025.134562

Discrete Lotka–Volterra systems with time delay and its stability analysis

Yusaku Yamamoto, Taisei Yamamoto, Takumi Kuroiwa, Kurumi Oka, Emiko Ishiwata, Masashi Iwasaki

Department of Applied Mathematics

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

Abstract

We propose an extension of the discrete-time Lotka–Volterra (dLV) equations describing predator–prey dynamics with time delay τ. Introducing time delay corresponds to considering multiple generations of each species and gives more expressive power to the model. For example, it becomes possible to model the situation where each individual is eaten only after it has grown up. In this paper, we focus on the system with minimal time delay (τ=1) and analyze the stability of the system. In particular, we prove that when the number of species is three, the system exhibits the same asymptotic behavior as the original dLV system. For more general cases with an arbitrary odd number of species, we investigate the local stability of fixed points of the system with the help of the center manifold theory. It is shown that the fixed points that correspond to the asymptotic states of the original dLV system are locally stable.

Original language	English
Article number	134562
Journal	Physica D: Nonlinear Phenomena
Volume	474
DOIs	https://doi.org/10.1016/j.physd.2025.134562
Publication status	Published - Apr 2025

Keywords

Center manifold theory
Conserved quantity
Difference equation
Lotka–Volterra system
Predator–prey dynamics
Stability analysis
Time delay

Access to Document

10.1016/j.physd.2025.134562

Cite this

@article{0c6cad76db57452b92d9bae80bcece5d,

title = "Discrete Lotka–Volterra systems with time delay and its stability analysis",

abstract = "We propose an extension of the discrete-time Lotka–Volterra (dLV) equations describing predator–prey dynamics with time delay τ. Introducing time delay corresponds to considering multiple generations of each species and gives more expressive power to the model. For example, it becomes possible to model the situation where each individual is eaten only after it has grown up. In this paper, we focus on the system with minimal time delay (τ=1) and analyze the stability of the system. In particular, we prove that when the number of species is three, the system exhibits the same asymptotic behavior as the original dLV system. For more general cases with an arbitrary odd number of species, we investigate the local stability of fixed points of the system with the help of the center manifold theory. It is shown that the fixed points that correspond to the asymptotic states of the original dLV system are locally stable.",

keywords = "Center manifold theory, Conserved quantity, Difference equation, Lotka–Volterra system, Predator–prey dynamics, Stability analysis, Time delay",

author = "Yusaku Yamamoto and Taisei Yamamoto and Takumi Kuroiwa and Kurumi Oka and Emiko Ishiwata and Masashi Iwasaki",

note = "Publisher Copyright: {\textcopyright} 2025",

year = "2025",

month = apr,

doi = "10.1016/j.physd.2025.134562",

language = "English",

volume = "474",

journal = "Physica D: Nonlinear Phenomena",

issn = "0167-2789",

publisher = "Elsevier B.V.",

}

TY - JOUR

T1 - Discrete Lotka–Volterra systems with time delay and its stability analysis

AU - Yamamoto, Yusaku

AU - Yamamoto, Taisei

AU - Kuroiwa, Takumi

AU - Oka, Kurumi

AU - Ishiwata, Emiko

AU - Iwasaki, Masashi

PY - 2025/4

Y1 - 2025/4

N2 - We propose an extension of the discrete-time Lotka–Volterra (dLV) equations describing predator–prey dynamics with time delay τ. Introducing time delay corresponds to considering multiple generations of each species and gives more expressive power to the model. For example, it becomes possible to model the situation where each individual is eaten only after it has grown up. In this paper, we focus on the system with minimal time delay (τ=1) and analyze the stability of the system. In particular, we prove that when the number of species is three, the system exhibits the same asymptotic behavior as the original dLV system. For more general cases with an arbitrary odd number of species, we investigate the local stability of fixed points of the system with the help of the center manifold theory. It is shown that the fixed points that correspond to the asymptotic states of the original dLV system are locally stable.

AB - We propose an extension of the discrete-time Lotka–Volterra (dLV) equations describing predator–prey dynamics with time delay τ. Introducing time delay corresponds to considering multiple generations of each species and gives more expressive power to the model. For example, it becomes possible to model the situation where each individual is eaten only after it has grown up. In this paper, we focus on the system with minimal time delay (τ=1) and analyze the stability of the system. In particular, we prove that when the number of species is three, the system exhibits the same asymptotic behavior as the original dLV system. For more general cases with an arbitrary odd number of species, we investigate the local stability of fixed points of the system with the help of the center manifold theory. It is shown that the fixed points that correspond to the asymptotic states of the original dLV system are locally stable.

KW - Center manifold theory

KW - Conserved quantity

KW - Difference equation

KW - Lotka–Volterra system

KW - Predator–prey dynamics

KW - Stability analysis

KW - Time delay

UR - https://www.scopus.com/pages/publications/85217791579

U2 - 10.1016/j.physd.2025.134562

DO - 10.1016/j.physd.2025.134562

M3 - Article

AN - SCOPUS:85217791579

SN - 0167-2789

VL - 474

JO - Physica D: Nonlinear Phenomena

JF - Physica D: Nonlinear Phenomena

M1 - 134562

ER -

Discrete Lotka–Volterra systems with time delay and its stability analysis

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this