Abstract
In the present paper, a fifth-order direct multistep block method is proposed for solving the second-order Delay Differential Equations (DDEs) directly with boundary conditions using constant step size. In many life sciences applications, a delay plays an essential role in modelling natural phenomena with data simulation. Thus, an efficient numerical method is needed for the numerical treatment of time delay in the applications. The proposed direct block method computes the numerical solutions at two points concurrently at each computed step along the interval. The types of delays involved in this research are constant delay, pantograph delay, and time-dependent delay. The shooting technique is utilized to deal with the boundary conditions by applying a Newton-like method to guess the next initial values. The analysis of the proposed method based on the order, consistency, convergence, and stability of the method are discussed in detail. Four tested problems are presented to measure the efficiency of the developed direct multistep block method. The numerical simulation indicates that the proposed direct multistep block method performs better than existing methods in terms of accuracy, total function calls, and execution times.
Highlights
Various problems in sciences and engineering may be interpreted as mathematical models in terms of Delay Differential Equations (DDEs)
DDEs exist in many real-life problems, such as in dengue fever diseases where time delay occurs between the mosquito bite until the body gets the infection
This paper aims to propose a direct multistep block method in the form of predictor corrector block method for solving the second-order DDEs with boundary conditions directly
Summary
Various problems in sciences and engineering may be interpreted as mathematical models in terms of Delay Differential Equations (DDEs). The study on solving the second-order DDEs of constant delay type numerically with boundary conditions started in the 1970s, where Nevers and Schmitt [3] solved this problem by using Euler’s method and shooting technique. The direct approach for solving second-order DDEs with initial conditions using a direct multistep method has been proposed by Seong et al [12,13,14]. Phang et al [17] has adapted the multiple shooting techniques and employed the three-step iterative method to produce the missing guessing values when solving BVPs problems with both Dirichlet and Neumann boundary conditions. This paper aims to propose a direct multistep block method in the form of predictor corrector block method for solving the second-order DDEs with boundary conditions directly. The numerical computations have been performed using the C language
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