Abstract

Stochastic discrete-event simulation has become one of the most-used tools for performance evaluation in science and engineering. But no innovation can replace the responsibility of simulators for obtaining credible results from their simulation experiments. In this paper we address the problem of the statistical correctness of simulation output data analysis, in the context of sequential steady-state stochastic simulation, conducted for studying long run behavior of stable systems. Such simulations are stopped as soon as the relative precision of estimates, defined as the relative half-width of confidence intervals at a specified confidence level, reaches the required level. We formulate basic rules for the proper experimental analysis of the coverage of steady-state interval estimators. Our main argument is that such an analysis should be done sequentially. The numerical results of our coverage analysis of the method of non-overlapping batch means and spectral analysis are presented, and compared with those obtained by the traditional, non-sequential approach. Two scenarios for stochastic simulation are considered: traditional sequential simulation on a single processor, and fast concurrent simulation based on multiple replications in parallel (MRIP), with multiple processors cooperating in the production of output data.

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