Higher Derivative versus Second Order Field Equations

Approximations where the derivatives are corrected so as to satisfy linear completeness on the derivatives are investigated. These techniques are used in particle methods and other mesh-free methods. The basic approximation is a Shepard interpolant which possesses only constant completeness. The der

In this paper, unconditionally stable higher-order accurate time step integration algorithms suitable for linear second-order di!erential equations based on the weighted residual method are presented. The second-order equations are manipulated directly. As in Part 1 of this paper, instead of specify

In Part 1 of this paper, the sampling grid points for the di erential quadrature method to give unconditionally stable higher-order accurate time step integration algorithms are proposed to solve ÿrst-order initial value problems. In this paper, the di erential quadrature method is extended to solve

## Abstract Galerkin finite element methods based on symmetric pyramid basis functions give poor accuracy when applied to second order elliptic equations with large coefficients of the first order terms. This is particularly so when the mesh size is such that oscillations are present in the numeric