Add to ORKGClassical asymptotic analysis of ordinary differential equations derives approximate solutions that are numerically stable. However, the analysis also leads to tedious expansions in powers of the relevant parameter for a particular problem. The expansions are replaced with integrals that can be evaluated by numerical integration. The resulting numerical solutions retain the linear independence that is the main advantage of asymptotic solutions. Examples, including the Falkner-Skan equation from laminar boundary layer theory, illustrate the method of asymptotic analysis with numerical integration
Matched asymptotic expansions (MAE) are used to obtain a first order approximation to the solution o...
Asymptotic expansion method for solving certain classes of singular perturbation problems with appli...
Airy-type asymptotic representations of a class of special functions are considered from a numerical...
New methods for integrating systems of stiff, nonlinear, first order, ordinary differential equation...
Nonlinear asymptotic integrators are applied to one-dimensional, nonlinear, autonomous, dissipative,...
Difference methods for asymptotic estimates of errors at numerical integration of systems of ordinar...
AbstractPresented in this paper is a new algorithm for the asymptotic expansion of a solution to an ...
When constructing an algorithm for the numerical integration of a differential equation, one must fi...
In this lecture notes, we will introduce Asymptotics, then we will give a short glimpse on Perturbat...
AbstractWe construct four finite-difference models for the Bessel differential equation. They corres...
Abstract: We consider an ordinary differential equation of a very general form. We show h...
This book presents a new method of asymptotic analysis of boundary-layer problems, the Successive Co...
A method for the numerical solution of differential equations of the boundary-layer type is presente...
AbstractSelf-similar solutions of boundary layer equations obey non-linear differential equations, a...
AbstractFor the uniform asymptotic expansio of Incomplete Cylindrical Functions of Bessel form a mod...
Matched asymptotic expansions (MAE) are used to obtain a first order approximation to the solution o...
Asymptotic expansion method for solving certain classes of singular perturbation problems with appli...
Airy-type asymptotic representations of a class of special functions are considered from a numerical...
New methods for integrating systems of stiff, nonlinear, first order, ordinary differential equation...
Nonlinear asymptotic integrators are applied to one-dimensional, nonlinear, autonomous, dissipative,...
Difference methods for asymptotic estimates of errors at numerical integration of systems of ordinar...
AbstractPresented in this paper is a new algorithm for the asymptotic expansion of a solution to an ...
When constructing an algorithm for the numerical integration of a differential equation, one must fi...
In this lecture notes, we will introduce Asymptotics, then we will give a short glimpse on Perturbat...
AbstractWe construct four finite-difference models for the Bessel differential equation. They corres...
Abstract: We consider an ordinary differential equation of a very general form. We show h...
This book presents a new method of asymptotic analysis of boundary-layer problems, the Successive Co...
A method for the numerical solution of differential equations of the boundary-layer type is presente...
AbstractSelf-similar solutions of boundary layer equations obey non-linear differential equations, a...
AbstractFor the uniform asymptotic expansio of Incomplete Cylindrical Functions of Bessel form a mod...
Matched asymptotic expansions (MAE) are used to obtain a first order approximation to the solution o...
Asymptotic expansion method for solving certain classes of singular perturbation problems with appli...
Airy-type asymptotic representations of a class of special functions are considered from a numerical...