A Comparison of Methods for Generating Normal Deviates on Digital Computers

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A Comparison of Methods for Generating Normal Deviates on Digital Computers

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Journal of the ACM (JACM) archive
Volume 6 , Issue 3 (July 1959) table of contents

Pages: 376 - 383

Year of Publication: 1959

ISSN:0004-5411

Author

Mervin E. Muller

Princeton University, Princeton, N. J., and International Business Machines Corp., New York, N. Y.

Publisher

ACM New York, NY, USA

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Downloads (6 Weeks): 7, Downloads (12 Months): 60, Citation Count: 9

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ABSTRACT

Two methods recently developed for generating normal deviates within a computer are reviewed along with earlier proposals. A comparison of the various methods for application on an IBM 704 is given. The new direct method gives higher accuracy than previous methods of comparable speed. The detailed inverse technique proposed yields accuracy comparable with, or better than, most previous proposals using about one-quarter the computing time.

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.

	1	G. E. P. Box ASp M. E. MULLER, A note on the generation of normM deviates. Ann. Math. Stat. 28 (1958), 610-611.
	2	JA~ES W. BUTLER, M:achine sampling from given probability distributions. Symposiuvar in Monte Carlo Methods, H. A. Meyer, ed., Wiley & Sons, New York, 1956, pp. 249-264.
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	5	Cecil Hastings, Approximations for Digital Computers, Princeton University Press, Princeton, NJ, 1955
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	12	M. E. MULLER, An inverse method for the generation o~ random normal deviates on large-scale computers. Math. Tables Aids Corap. 12 (1958), 167-174.
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	14	~ymposium in Monte Carlo Methods, H. A. Meyer, ed. (Gainesville). John Wiley & Sons, New York, 1956.
	15	T~ RAND GO~P.: O~e Million Random Digits and 100,000 Normal Deviates. The Free Press, Glencoe, Illinois, 1955.
	16	O. TxussKr xz~v J. Torn, Generation and testing of pseudo random numbers. ~yraposium in Monte Carlo Methods, H. A. Meyers, ed., John Wiley & Sons, blew York, 1956, pp. 15--27.
	17	D. TEIcn~oEw, Distribution sampling with high speed computers. Ph.D. Thesis, University of North Carolina, 1953.
	18	D. F. VOTAW ANX) J. A. RAFFER~V, High speed sampling. Ma~h. Tables Aids Comp. 5 (105~), l-s.
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CITED BY 9

	Winnie Chen , Roger L. Burford, Quality evaluation of some combinations of unit uniform random number generators and unit normal transformation algorithms, Proceedings of the 14th annual symposium on Simulation, p.129-149, March 17-20, 1981, Tampa, Florida, United States
	Donald R. Barr , Norman L. Slezak, A comparison of multivariate normal generators, Communications of the ACM, v.15 n.12, p.1048-1049, Dec. 1972
	Joseph L. Balintfy, Stochastic sensitivity analysis of linear programs by simulation techniques, Proceedings of the fourth annual conference on Applications of simulation, p.130-133, December 09-11, 1970, New York, New York, United States
	W. H. Payne, Normal Random Numbers: Using Machine Analysis to Choose the Best Algorithm, ACM Transactions on Mathematical Software (TOMS), v.3 n.4, p.346-358, Dec. 1977
	R. De Vogelaere, Remark on algorithm 178: Direct search, Communications of the ACM, v.11 n.7, p.498, July 1968
	James R. Bell, Algorithm 334: Normal random deviates, Communications of the ACM, v.11 n.7, p.498, July 1968
	Dong-U Lee , Wayne Luk , John D. Villasenor , Peter Y. K. Cheung, A Gaussian Noise Generator for Hardware-Based Simulations, IEEE Transactions on Computers, v.53 n.12, p.1523-1534, December 2004
	David B. Thomas , Wayne Luk , Philip H.W. Leong , John D. Villasenor, Gaussian random number generators, ACM Computing Surveys (CSUR), v.39 n.4, p.11-es, 2007
	Amirhossein Alimohammad , Saeed Fouladi Fard , Bruce F. Cockburn , Christian Schlegel, A compact and accurate Gaussian variate generator, IEEE Transactions on Very Large Scale Integration (VLSI) Systems, v.16 n.5, p.517-527, May 2008