We construct asymptotic expansions for ordinary differential equations with highly oscillatory forcing terms, focussing on the case of multiple, non-commensurate frequencies. We derive an asymptotic expansion in inverse powers of the oscillatory parameter and use its truncation as an exceedingly effective means to discretize the differential equation in question. Numerical examples illustrate the effectiveness of the method
We present a numerical scheme for an efficient discretization of nonlinear systems of differential e...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
We construct asymptotic expansions for ordinary differential equations with highly oscillatory forci...
We construct asymptotic expansions for ordinary differential equations with highly oscillatory forci...
We describe an asymptotic method for approximating solutions of systems of ODEs with oscillatory fo...
We describe an asymptotic method for approximating solutions of systems of ODEs with oscillatory fo...
We present a method to compute efficiently solutions of systems of ordinary differential equations t...
We present a method to compute efficiently solutions of systems of ordinary differential equations t...
We present a method to compute efficiently solutions of systems of ordinary differential equations t...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
Abstract. We present a method to compute efficiently solutions of systems of ordinary differ-ential ...
We present a numerical scheme for an efficient discretization of nonlinear systems of differential e...
We present a numerical scheme for an efficient discretization of nonlinear systems of differential e...
We present a numerical scheme for an efficient discretization of nonlinear systems of differential e...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
We construct asymptotic expansions for ordinary differential equations with highly oscillatory forci...
We construct asymptotic expansions for ordinary differential equations with highly oscillatory forci...
We describe an asymptotic method for approximating solutions of systems of ODEs with oscillatory fo...
We describe an asymptotic method for approximating solutions of systems of ODEs with oscillatory fo...
We present a method to compute efficiently solutions of systems of ordinary differential equations t...
We present a method to compute efficiently solutions of systems of ordinary differential equations t...
We present a method to compute efficiently solutions of systems of ordinary differential equations t...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
Abstract. We present a method to compute efficiently solutions of systems of ordinary differ-ential ...
We present a numerical scheme for an efficient discretization of nonlinear systems of differential e...
We present a numerical scheme for an efficient discretization of nonlinear systems of differential e...
We present a numerical scheme for an efficient discretization of nonlinear systems of differential e...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...
We present a method to compute efficiently solutions of systems of ordinary differential equations (...