Journal of Computational and Applied Mathematics - Orthogonal polynomials and numerical methods
A modified Chebyshev pseudospectral method with an O(N–1) time step restriction
Journal of Computational Physics
A spectral embedding method applied to the advection-diffusion equation
Journal of Computational Physics
On the Gibbs Phenomenon and Its Resolution
SIAM Review
On a high order numerical method for functions with singularities
Mathematics of Computation
A comparison of numerical algorithms for Fourier extension of the first, second, and third kinds
Journal of Computational Physics
On Some Applications of the Superposition Principle with Fourier Basis
SIAM Journal on Scientific Computing
ACM Transactions on Mathematical Software (TOMS)
SIAM Journal on Scientific Computing
Journal of Computational Physics
Is Gauss Quadrature Better than Clenshaw-Curtis?
SIAM Review
New Quadrature Formulas from Conformal Maps
SIAM Journal on Numerical Analysis
Journal of Computational Physics
Spectral domain embedding for elliptic PDEs in complex domains
Journal of Computational and Applied Mathematics
On the Fourier Extension of Nonperiodic Functions
SIAM Journal on Numerical Analysis
A spectral fictitious domain method with internal forcing for solving elliptic PDEs
Journal of Computational Physics
Journal of Computational Physics
A Fast Algorithm for Fourier Continuation
SIAM Journal on Scientific Computing
Approximation error in regularized SVD-based Fourier continuations
Applied Numerical Mathematics
| Hi-index | 7.29 |
Functions that are smooth but non-periodic on a certain interval possess Fourier series that lack uniform convergence and suffer from the Gibbs phenomenon. However, they can be represented accurately by a Fourier series that is periodic on a larger interval. This is commonly called a Fourier extension. When constructed in a particular manner, Fourier extensions share many of the same features of a standard Fourier series. In particular, one can compute Fourier extensions which converge spectrally fast whenever the function is smooth, and geometrically fast if the function is analytic, much the same as the Fourier series of a smooth/analytic and periodic function. With this in mind, the purpose of this paper is to describe, analyse and explain the observation that Fourier extensions, much like classical Fourier series, also have excellent resolution properties for representing oscillatory functions. The resolution power, or required number of degrees of freedom per wavelength, depends on a user-controlled parameter and, as we show, it varies between 2 and @p. The former value is optimal and is achieved by classical Fourier series for periodic functions, for example. The latter value is the resolution power of algebraic polynomial approximations. Thus, Fourier extensions with an appropriate choice of parameter are eminently suitable for problems with moderate to high degrees of oscillation.