Correlation-induction techniques for estimating quantiles in simulation experiments

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Correlation-induction techniques for estimating quantiles in simulation experiments

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Winter Simulation Conference archive
Proceedings of the 27th conference on Winter simulation table of contents

Arlington, Virginia, United States

Pages: 268 - 277

Year of Publication: 1995

ISBN:0-7803-3018-8

Authors

Athanassios N. Avramidis	SABRE Decision Technologies, 116 ter Rue de Saussure, 75017 Paris, France
James R. Wilson	Department of Industrial Engineering, North Carolina State University, Raleigh, North Carolina

Sponsors

IIE : Institute of Industrial Engineers
SCS : Society for Computer Simulation
ASA : American Statistical Association
NIST : National Institue of Standards & Technology
IEEE-CS : Computer Society
IEEE-SMCS : Systems, Man & Cybernetics Society
ACM: Association for Computing Machinery
INFORMS/CS : Computer Science TC
SIGSIM: ACM Special Interest Group on Simulation and Modeling

Publisher

IEEE Computer Society Washington, DC, USA

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Downloads (6 Weeks): 3, Downloads (12 Months): 20, Citation Count: 1

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ABSTRACT

To estimate selected quantiles of the response of a finite-horizon simulation, we develop statistical methods based on correlation-induction techniques for variance reduction, with emphasis on antithetic variates and Latin hypercube sampling. The proposed multiple-sample quantile estimator is the average of negatively correlated quantile estimators computed from disjoint samples of the response, where negative correlation is induced between corresponding responses in different samples while mutual independence of responses is maintained within each sample. The proposed single-sample quantile estimator is computed from negatively correlated responses within one overall sample. We establish a central limit theorem for the single-sample estimator based on Latin hypercube sampling, showing that asymptotically this estimator is unbiased and has smaller variance than the comparable direct-simulation estimator based on independent replications. We also show that if the response is monotone in the simulation's random-number inputs and if the response satisfies some other regularity conditions, then asymptotically the multiple-sample estimator is unbiased and has smaller mean square error than the direct-simulation estimator.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

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