Barycentric rational interpolation method for numerical investigation of magnetohydrodynamics nanofluid flow and heat transfer in nonparallel plates with thermal radiation

Abstract: In this study, the problem of heat transfer in the steady two-dimensional flow of an incompressible viscous magnetohydrodynamics nanofluid from a sink or source between two shrinkable or stretchable plates under the effect of thermal radiation has been studied. The governing differential equations have been solved numerically using a collocation method based on the barycentric rational basis functions. This method employs the derivative operational matrix of the barycentric rational bases and the weights that … Show more

“…So in this case, the FH family of interpolants is a better choice. During the last few years, some numerical methods based on the LBRIs with Floater-Hormann weights have been introduced to approximate the solutions of the nonlinear differential equations, [55][56][57][58] the Volterra integral equations (VIEs), 59 stiff VIEs, 60 weakly singular VIEs, 61,62 VIDEs, 63,64 delay VIDEs, 65 and high-dimensional Fredholm integral equations (FIEs). 66 The main purpose of this work is to develop a computational method based on an extended form of the interpolating scaling functions (ISFs), named the piecewise barycentric interpolating functions (PBIFs), with the associated operational matrices of integral and product for the VIDE (1).…”

“…So in this case, the FH family of interpolants is a better choice. During the last few years, some numerical methods based on the LBRIs with Floater–Hormann weights have been introduced to approximate the solutions of the nonlinear differential equations, 55–58 the Volterra integral equations (VIEs), 59 stiff VIEs, 60 weakly singular VIEs, 61,62 VIDEs, 63,64 delay VIDEs, 65 and high‐dimensional Fredholm integral equations (FIEs) 66 …”

Piecewise barycentric interpolating functions for the numerical solution of Volterra integro‐differential equations

“…So in this case, the FH family of interpolants is a better choice. During the last few years, some numerical methods based on the LBRIs with Floater-Hormann weights have been introduced to approximate the solutions of the nonlinear differential equations, [55][56][57][58] the Volterra integral equations (VIEs), 59 stiff VIEs, 60 weakly singular VIEs, 61,62 VIDEs, 63,64 delay VIDEs, 65 and high-dimensional Fredholm integral equations (FIEs). 66 The main purpose of this work is to develop a computational method based on an extended form of the interpolating scaling functions (ISFs), named the piecewise barycentric interpolating functions (PBIFs), with the associated operational matrices of integral and product for the VIDE (1).…”

“…So in this case, the FH family of interpolants is a better choice. During the last few years, some numerical methods based on the LBRIs with Floater–Hormann weights have been introduced to approximate the solutions of the nonlinear differential equations, 55–58 the Volterra integral equations (VIEs), 59 stiff VIEs, 60 weakly singular VIEs, 61,62 VIDEs, 63,64 delay VIDEs, 65 and high‐dimensional Fredholm integral equations (FIEs) 66 …”

Piecewise barycentric interpolating functions for the numerical solution of Volterra integro‐differential equations

A Novel Numerical Approach for Simulating the Nonlinear MHD Jeffery–Hamel Flow Problem

A high-order reliable and efficient Haar wavelet collocation method for nonlinear problems with two point-integral boundary conditions