An explicit, unconditionally stable, time integration algorithm with a controlled accuracy

An accurate algorithm for the integration of the equations of motion arising in structural dynamics is presented. The algorithm is an unconditionally stable single-step implicit algorithm incorporating algorithmic damping. The displacement for a Single-Degree-of-Freedom system is approximated within

## Abstract In this work, we present a new and efficient numerical method to obtain an unconditionally stable solution for the time‐domain magnetic‐field integral equation (TD‐MFIE) for arbitrarily closed conducting bodies. This novel method does not utilize the customary marching‐on‐in‐time (MOT)

This paper presents a new dead-time compensator for stable and integrating processes when a reduced model of the process is considered. The output is estimated from a discrete time representation of the continuous time model and the tuning of the controllers can be made by any classical control desi

## Abstract In this paper, by analyzing the numerical dispersion property of an unconditionally stable three‐dimensional alternating direction implicit finite‐difference time‐domain (ADI‐FDTD) method, the influence of the time steps on the numerical dispersion error of the method is investigated. I