Abstract
Predator-prey models are the building blocks of the ecosystems as biomasses are grown out of their resource masses. Different relationships exist between these models as different interacting species compete, metamorphosis occurs and migrate strategically aiming for resources to sustain their struggle to exist. To numerically investigate these assumptions, ordinary differential equations are formulated, and a variety of methods are used to obtain and compare approximate solutions against exact solutions, although most numerical methods often require heavy computations that are time-consuming. In this paper, the traditional differential transform (DTM) method is implemented to obtain a numerical approximate solution to prey-predator models. The solution obtained with DTM is convergent locally within a small domain. The multi-step differential transform method (MSDTM) is a technique that improves DTM in the sense that it increases its interval of convergence of the series expansion. One predator-one prey and two-predator-one prey models are considered with a quadratic term which signifies other food sources for its feeding. The result obtained numerically and graphically shows point DTM diverges. The advantage of the new algorithm is that the obtained series solution converges for wide time regions and the solutions obtained from DTM and MSDTM are compared with solutions obtained using the classical Runge-Kutta method of order four. The results demonstrated is that MSDTM computes fast, is reliable and gives good results compared to the solutions obtained using the classical Runge-Kutta method.
Highlights
The purpose of this paper is to exclusively employ the approach of differential transform method (DTM), multi-step differential transformation method (MSDTM), and Runge-Kutta method
The multi-step differential transform method (MSDTM) is a technique that improves DTM in the sense that it increases its interval of convergence of the series expansion
The advantage of the new algorithm is that the obtained series solution converges for wide time regions and the solutions obtained from DTM and MSDTM are compared with so-lutions obtained using the classical Runge-Kutta method of order four
Summary
The purpose of this paper is to exclusively employ the approach of differential transform method (DTM), multi-step differential transformation method (MSDTM), and Runge-Kutta method This approach is a comparative analysis of predatorprey models that is re-modified and model real-life situations. An Approximate Solution to Predator-prey Models Using The Differential Transform Method and Multi-step Differential As known that ODEs (linear and non-linear) are used to model realistic situation by researchers in different fields such as Biology (interaction between organism, bacteria and parasites[1], [2], [3]), Chemistry (chemical kinetics, rate of chemical reactions [4],[5]), Engineering (suspension systems, electric circuit, oscillations and vibrations [6], [7], [8]), Annular habitat ([9],[10]) and parameters estimation of predator-
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