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Nearly Optimal Bernoulli Factories for Linear Functions

Part of: Probabilistic methods, simulation and stochastic differential equations Theory of computing

Published online by Cambridge University Press:  01 February 2016

MARK HUBER
MARK HUBER*
Affiliation:
Claremont McKenna College, 850 Columbia Avenue, Claremont, CA 91711, USA (e-mail: mhuber@cmc.edu)
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Abstract

Suppose that X1, X2, . . . are independent identically distributed Bernoulli random variables with mean p. A Bernoulli factory for a function f takes as input X1, X2, . . . and outputs a random variable that is Bernoulli with mean f(p). A fast algorithm is a function that only depends on the values of X1, . . ., XT, where T is a stopping time with small mean. When f(p) is a real analytic function the problem reduces to being able to draw from linear functions Cp for a constant C > 1. Also it is necessary that Cp ⩽ 1 − ε for known ε > 0. Previous methods for this problem required extensive modification of the algorithm for every value of C and ε. These methods did not have explicit bounds on $\mathbb{E}[T]$ as a function of C and ε. This paper presents the first Bernoulli factory for f(p) = Cp with bounds on $\mathbb{E}[T]$ as a function of the input parameters. In fact, supp∈[0,(1−ε)/C]$\mathbb{E}[T]$ ≤ 9.5ε−1C. In addition, this method is very simple to implement. Furthermore, a lower bound on the average running time of any Cp Bernoulli factory is shown. For ε ⩽ 1/2, supp∈[0,(1−ε)/C]$\mathbb{E}[T]$≥0.004Cε−1, so the new method is optimal up to a constant in the running time.

MSC classification

Primary: 65C50: Other computational problems in probability
Secondary: 68Q17: Computational difficulty of problems (lower bounds, completeness, difficulty of approximation, etc.)
Type
Paper
Information
Combinatorics, Probability and Computing , Volume 25 , Issue 4 , July 2016 , pp. 577 - 591
Copyright
Copyright © Cambridge University Press 2016 

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References

[1] Asmussen, S., Glynn, P. W. and Thorisson, H. (1992) Stationarity detection in the initial transient problem. ACM Trans. Model. Comput. Simul. 2 130157.Google Scholar
[2] Dagum, P., Karp, R., Luby, M. and Ross, S. (2000) An optimal algorithm for Monte Carlo estimation. SIAM J. Comput. 29 14841496.CrossRefGoogle Scholar
[3] Durrett, R. (2005) Probability: Theory and Examples, third edition, Brooks/Cole.Google Scholar
[4] Flegal, J. and Herbei, R. (2012) Exact sampling for intractable probability distributions via a Bernoulli factory. Electron. J. Statist. 6 1037.CrossRefGoogle Scholar
[5] Keane, M. S. and O'Brien, G. L. (1994) A Bernoulli factory. ACM Trans. Model. Comput. Simul. 4 213219.Google Scholar
[6] atuszyński, K., Kosmidis, I., Papaspiliopoulos, O. and Roberts, G. O. (2011) Simulation events of unknown probability via reverse time martingales. Random Struct. Alg. 38 441452.Google Scholar
[7] Nacu, S. and Peres, Y. (2005) Fast simulation of new coins from old. Ann. Appl. Probab. 15 93115.Google Scholar
[8] Thomas, A. C. and Blanchet, J. (2011) A practical implementation of the Bernoulli factory. arXiv:1105.2508 Google Scholar
[9] von Neumann, J. (1951) Various techniques used in connection with random digits. In Monte Carlo Methods, Vol. 12 of Applied Mathematics Series, National Bureau of Standards.Google Scholar