Add to ORKGA spectral collocation method based on rational interpolants and adaptive grid points is presented. The rational interpolants approximate analytic functions with exponential accuracy by using prescribed barycentric weights and transformed Chebyshev points. The locations of the grid points are adapted to singularities of the underlying solution, and the locations of these singularities are approximated by the locations of poles of Chebyshev-Padé approximants. Numerical experiments on two time-dependent problems, one with finite time blow-up and one with a moving front, indicate that the method far outperforms the standard Chebyshev spectral collocation method for problems whose solutions have singularities in the complex plan close to [-1,1]
This is the published version, also available here: http://dx.doi.org/10.1137/S1064827595291984.The ...
The Lanczos method and its variants can be used to solve efficiently the rational interpolation...
AbstractOver the rectangle Ω = (−1. 1) × (−π, π) of R2, interpolation involving algebraic polynomial...
We present a numerical procedure to compute the nodes and weights in rational Gauss-Chebyshev quadra...
For the numerical solution of differential equations spectral methods typically give excellent accur...
AbstractA new kind of numerical method based on rational spectral collocation with the sinh transfor...
AbstractOver the rectangle Ω = (−1. 1) × (−π, π) of R2, interpolation involving algebraic polynomial...
A Chebyshev or Fourier series may be evaluated on the standard collocation grid by the fast Fourier ...
In this manuscript, we will examine several methods of interpolation, with an emphasis on Chebyshev ...
AbstractClassical rational interpolation is known to suffer from several drawbacks, such as unattain...
AbstractWe introduce the collocation method based on linear rational interpolation for solving gener...
The purpose of this paper is to investigate the use of rational Chebyshev (RC) functions for solving...
The effect of mappings on the approximation, by Chebyshev collocation, of functions which exhibit lo...
AbstractWe study rational interpolation formulas on the interval [−1,1] for a given set of real or c...
This is the published version, also available here: http://dx.doi.org/10.1137/S1064827595291984.The ...
This is the published version, also available here: http://dx.doi.org/10.1137/S1064827595291984.The ...
The Lanczos method and its variants can be used to solve efficiently the rational interpolation...
AbstractOver the rectangle Ω = (−1. 1) × (−π, π) of R2, interpolation involving algebraic polynomial...
We present a numerical procedure to compute the nodes and weights in rational Gauss-Chebyshev quadra...
For the numerical solution of differential equations spectral methods typically give excellent accur...
AbstractA new kind of numerical method based on rational spectral collocation with the sinh transfor...
AbstractOver the rectangle Ω = (−1. 1) × (−π, π) of R2, interpolation involving algebraic polynomial...
A Chebyshev or Fourier series may be evaluated on the standard collocation grid by the fast Fourier ...
In this manuscript, we will examine several methods of interpolation, with an emphasis on Chebyshev ...
AbstractClassical rational interpolation is known to suffer from several drawbacks, such as unattain...
AbstractWe introduce the collocation method based on linear rational interpolation for solving gener...
The purpose of this paper is to investigate the use of rational Chebyshev (RC) functions for solving...
The effect of mappings on the approximation, by Chebyshev collocation, of functions which exhibit lo...
AbstractWe study rational interpolation formulas on the interval [−1,1] for a given set of real or c...
This is the published version, also available here: http://dx.doi.org/10.1137/S1064827595291984.The ...
This is the published version, also available here: http://dx.doi.org/10.1137/S1064827595291984.The ...
The Lanczos method and its variants can be used to solve efficiently the rational interpolation...
AbstractOver the rectangle Ω = (−1. 1) × (−π, π) of R2, interpolation involving algebraic polynomial...