From massively parallel algorithms and fluctuating time horizons to nonequilibrium surface growth
Physical review letters, 2000•APS
We study the asymptotic scaling properties of a massively parallel algorithm for discrete-
event simulations where the discrete events are Poisson arrivals. The evolution of the
simulated time horizon is analogous to a nonequilibrium surface. Monte Carlo simulations
and a coarse-grained approximation indicate that the macroscopic landscape in the steady
state is governed by the Edwards-Wilkinson Hamiltonian. Since the efficiency of the
algorithm corresponds to the density of local minima in the associated surface, our results …
event simulations where the discrete events are Poisson arrivals. The evolution of the
simulated time horizon is analogous to a nonequilibrium surface. Monte Carlo simulations
and a coarse-grained approximation indicate that the macroscopic landscape in the steady
state is governed by the Edwards-Wilkinson Hamiltonian. Since the efficiency of the
algorithm corresponds to the density of local minima in the associated surface, our results …
Abstract
We study the asymptotic scaling properties of a massively parallel algorithm for discrete-event simulations where the discrete events are Poisson arrivals. The evolution of the simulated time horizon is analogous to a nonequilibrium surface. Monte Carlo simulations and a coarse-grained approximation indicate that the macroscopic landscape in the steady state is governed by the Edwards-Wilkinson Hamiltonian. Since the efficiency of the algorithm corresponds to the density of local minima in the associated surface, our results imply that the algorithm is asymptotically scalable.
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