Paper: Generalized Multiple Scale Reproducing Kernel Particle Methods
W. K. Liu, Y. Chen, R. A. Uras and C. T. Chang
"Computer Methods in Applied Mechanics and Engineering", Vol. 139, pp.
91-158, 1996
Abstract
An approach to unify reproducing kernel methods under one large umbrella
and an extension to include time and spatial shifting are proposed. The
study is divided into three major topics. The groundwork is set by revisiting
the Fourier analysis of discrete systems. The multiresolution concept and
its significance in devising the reproducing kernel methods and its discrete
counterpart, reproducing kernel particle methods, are explained. An edge
detection technique based on multiresolution analysis is developed. This
wavelet approach together with particle methods give rise to a straight-forward
hp-adaptivity algorithm. By using this groundwork, a Hermite reproducing
kernel method is also proposed, and its relation to wavelet methods is
presented. It is also shown that the new approach generalizes existing
kernel methods, and it can easily be degenerated into other widely used
methods such as partition of unity, moving least square interpolants, smooth
particle hydrodynamics, scaling functions and wavelets, and multiple scale
analysis. Furthermore, the Hermite reproducing kernel particle method,
a particle based discrete version of the Hermite reproducing kernel method
is developed. Finally, multiple-scale methods based on frequency and wave
number shifting techniques are presented. A full-fledged stability analysis
is also presented for Newmark time integration schemes for the low frequency
equation. Numerical examples are presented throughout the paper to illustrate
the flexibility and accuracy of this class of multiple scale methods.
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Professor Wing Kam Liu
Send email: w-liu@nwu.edu