Supervised neural learning for the predator-prey delay differential system of Holling form-III

Ruttanaprommarin, Naret; Sabir, Zulqurnain; Saïd, Salem Ben; Raja, Muhammad Asif Zahoor; Bhatti, Saira; Weera, Wajaree; Botmart, Thongchai

doi:10.3934/math.20221101

MATH

2022

DOI: 10.3934/math.20221101

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Supervised neural learning for the predator-prey delay differential system of Holling form-III

Naret Ruttanaprommarin

Zulqurnain Sabir

Salem Ben Saïd

et al.

Abstract: <abstract> <p>The purpose of this work is to present the stochastic computing study based on the artificial neural networks (ANNs) along with the scaled conjugate gradient (SCG), ANNs-SCG for solving the predator-prey delay differential system of Holling form-III. The mathematical form of the predator-prey delay differential system of Holling form-III is categorized into prey class, predator category and the recent past effects. Three variations of the predator-prey delay differential system of Ho… Show more

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Cited by 4 publications

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“…We can also consider impulsive delayed harvesting or stage structure of prey/predator populations, which will lead to richer dynamics [30]. In addition, trying to solve system (6) using an intelligent computational solver, or different numerical methods such as the Galerkin method or Legendre wavelet algorithm will also be interesting work [31][32][33].…”

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Dynamics of a Predator–Prey Model with Impulsive Diffusion and Transient/Nontransient Impulsive Harvesting

2023

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Harvesting is one of the ways for humans to realize economic interests, while unrestricted harvesting will lead to the extinction of populations. This paper proposes a predator–prey model with impulsive diffusion and transient/nontransient impulsive harvesting. In this model, we consider both impulsive harvesting and impulsive diffusion; additionally, predator and prey are harvested simultaneously. First, we obtain the subsystems of the system in prey extinction and predator extinction. We obtain the fixed points of the subsystems by the stroboscopic map theories of impulsive differential equations and analyze their stabilities. Further, we establish the globally asymptotically stable conditions for the prey/predator-extinction periodic solution and the trivial solution of the system, and then the sufficient conditions for the permanence of the system are given. We also perform several numerical simulations to substantiate our results. It is shown that the transient and nontransient impulsive harvesting have strong impacts on the persistence of the predator–prey model.

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Dynamics of a Predator–Prey Model with Impulsive Diffusion and Transient/Nontransient Impulsive Harvesting

2023

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Utilizing memory effects to enhance resilience in disease-driven prey-predator systems under the influence of global warming

Thirthar,

Sk,

Mondal

et al. 2023

J. Appl. Math. Comput.

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This research paper presents an eco-epidemiological model that investigates the intricate dynamics of a predator–prey system, considering the impact of fear-induced stress, hunting cooperation, global warming, and memory effects on species interactions. The model employs fractional-order derivatives to account for temporal dependencies and memory in ecological processes. By incorporating these factors, we aim to provide a more comprehensive understanding of the underlying mechanisms that govern the stability and behavior of ecological systems. Mathematically we investigate system’s existence, equilibria and their stability. Moreover, global stability and hopf bifurcation also analyzed in this study. Numerical simulations have been performed to validate the analytical results. We find that the coexistence equilibrium is stable under specific conditions, along with the predator equilibrium and the disease-free equilibrium. Bifurcation analyses demonstrate the intricate behavior of species densities in response to changes in model parameters. Fear and global warming are found to stabilize the system, while cooperation and additional food for predators lead to destabilization. Additionally, the influence of species memory has been explored. We observe that memory tends to stabilize the system as species memory levels increase.

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Modeling the dynamics of Diamondback Moth infestations on cabbage biomass

Paul,

Mayengo,

Daudi

2023

Informatics in Medicine Unlocked

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Supervised neural learning for the predator-prey delay differential system of Holling form-III

Cited by 4 publications

References 50 publications

Dynamics of a Predator–Prey Model with Impulsive Diffusion and Transient/Nontransient Impulsive Harvesting

Dynamics of a Predator–Prey Model with Impulsive Diffusion and Transient/Nontransient Impulsive Harvesting

Utilizing memory effects to enhance resilience in disease-driven prey-predator systems under the influence of global warming

Modeling the dynamics of Diamondback Moth infestations on cabbage biomass

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