Numerical stabilizers and computing time for second-order accurate schemes

## A BS TRA CT A new second order accurate scheme for spherically symmetric flow field prediction, based on a plane wave one-dimensional algorithm described by Nessyahu and Tadmor (J. Comp. Phys., 87 (1990) is presented. Proof of the second-order accuracy property is outlined.

## Abstract The potential for developing higher‐order finite‐difference time‐domain (FDTD) schemes with reduced phase errors is investigated in the present paper. Using the classic (2,4) FDTD method as the basis of this study, electromagnetic wave propagation is accurately reproduced in the discret

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

A second-order accurate difference scheme is developed to study cavitation in unsteady, one-dimensional, inviscid, compressible flows of water with gas. The scheme can capture shock waves, interfaces separating gas and water, as well as cavitation zones that are modelled as vacuum states, and it tak