Abstract
This paper is concerned with the Lane–Emden boundary value problems arising in many real-life problems. Here, we discuss two numerical schemes based on Jacobi and Bernoulli wavelets for the solution of the governing equation of electrohydrodynamic flow in a circular cylindrical conduit, nonlinear heat conduction model in the human head, and non-isothermal reaction–diffusion model equations in a spherical catalyst and a spherical biocatalyst. These methods convert each problem into a system of nonlinear algebraic equations, and on solving them by Newton’s method, we get the approximate analytical solution. We also provide the error bounds of our schemes. Furthermore, we also compare our results with the results in the literature. Numerical experiments show the accuracy and reliability of the proposed methods.
Highlights
The solution of Emden–Fowler type equation is vital because of its numerous applications in engineering and technical problems
We introduce two methods based on Jacobi and Bernoulli wavelets for solving models of electrohydrodynamic flow in a circular cylindrical conduit, nonlinear heat conduction model in the human head, spherical catalyst equation, and spherical biocatalyst equation
7 Conclusion In this paper, we have studied EHD flow in a charged circular cylinder conduit, nonlinear heat conduction model in the human head, non-isothermal reaction–diffusion model equations in a spherical catalyst, and non-isothermal reaction–diffusion model equations
Summary
The solution of Emden–Fowler type equation is vital because of its numerous applications in engineering and technical problems. 1.1 Model of electrohydrodynamic (EHD) flow in a circular cylindrical conduit The effect of the electric and magnetic field on fluid has been studied by many researchers. We introduce two methods based on Jacobi and Bernoulli wavelets for solving models of electrohydrodynamic flow in a circular cylindrical conduit, nonlinear heat conduction model in the human head, spherical catalyst equation, and spherical biocatalyst equation. These wavelets transform these model equations into a system of nonlinear algebraic equations, and on solving them, we get the unknown wavelet coefficients.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
