Abstract
The current study investigates the predator-prey problem with assumptions that interaction of predation has a little or no effect on prey population growth and the prey’s grow rate is time dependent. The prey is assumed to follow the Gompertz growth model and the respective predator growth function is constructed by solving ordinary differential equations. The results show that the predator population model is found to be a function of the well known exponential integral function. The solution is also given in Taylor’s series. Simulation study shows that the predator population size eventually converges either to a finite positive limit or zero or diverges to positive infinity. Under certain conditions, the predator population converges to the asymptotic limit of the prey model. More results are included in the paper.
Highlights
The predator-prey problem has been interesting to many researchers [1]-[7]
We assume that the prey population growths naturally with no interaction effect due to predation and rate of growth is non-constant
The predator-prey equations are solved considering prey grows as Gompertz model
Summary
Modelling population growth of interacting species involves differential equations [1] [2]. Decrease, or have little effect on the strength, impact or importance of interspecific competition [3]. It is discussed in [4] that the net effects of interspecific species interactions on individuals and populations vary in both sign (positive, zero, negative) and magnitude (strong to weak). The predator-prey problem with the assumptions of little or no effect of predation on the prey population growth is studied in [6] [7]. There are several options to consider among the generalized growth models [8] These include, for example, generalized logistic, particular case of logistic, logistic, Richards, Von Bertalanffy, Brody, Gompertz, generalized weibull, weibull, monomolecular, mitscherlich and more.
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