Simulations of dynamically triangulated gravity — an algorithm for arbitrary dimension

Computer simulation techniques have proven to be quite useful for studying the structure of particulates produced by the process of growth through the aggregation of smaller particles. In this paper we introduce an efficient algorithm for use in the computer simulation of the kinetics of the growth

tasks, which results in considerable CPU time savings. This method is based on selectively limiting the calculation of A method of optimizing molecular dynamics calculations is presented. The method employs multiple time steps across the computhe forces and the neighbor list updating, according to t

A fast efficient algorithm may be used for integrating very large (n >> 10) stiffdifferential equations of the type R = Ax + Bu + f(x, t), x(t0) = x0, wh ere f(x, t) has a small Lipschitz constant. Summary--An algorithm for integrating high dimensional stiff nonlinear differential equations of the

The Verlet, Verlet leap frog, Gear fixed time step. Gear variable time step, Runge-Kutta, and Gauss-Radau algorithms have been compared using trajectory data obtained from the integration of a one-dimensional diatomic chain under constant pressure. Investigation into the times of local and normal mo

Within molecular dynamics simulations of protein᎐solvent systems the exact evaluation of long-range Coulomb interactions is computationally demanding and becomes prohibitive for large systems. Conventional truncation methods circumvent that computational problem, but are hampered by serious artifact