A three-point finite difference method for a class of singular two-point boundary value problems
Journal of Computational and Applied Mathematics
Variational approach to the Lane--Emden equation
Applied Mathematics and Computation
Computers & Mathematics with Applications
A Taylor polynomial approach for solving differential-difference equations
Journal of Computational and Applied Mathematics
On the numerical solution of differential equations of Lane-Emden type
Computers & Mathematics with Applications
On using a modified Legendre-spectral method for solving singular IVPs of Lane-Emden type
Computers & Mathematics with Applications
Computers & Mathematics with Applications
An Algorithm for Solving Nonlinear Differential-Difference Models
Computational Mathematics and Modeling
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In this paper, a numerical method which produces an approximate polynomial solution is presented for solving the high-order linear singular differential-difference equations. With the aid of Bessel polynomials and collocation points, this method converts the singular differential-difference equations into the matrix equation. The matrix equation corresponds to a system of linear equations with the unknown Bessel coefficients. This method gives the analytic solutions when the exact solutions are polynomials. Finally, some experiments and their numerical solutions are given; by comparing the numerical results obtained from the other methods, we show the high accuracy and efficiency of the proposed method. All of the numerical computations have been performed on a PC using some programs written in MATLAB v7.6.0 (R2008a).