Open Access
May 2013 Total variation error bounds for geometric approximation
Erol A. Peköz, Adrian Röllin, Nathan Ross
Bernoulli 19(2): 610-632 (May 2013). DOI: 10.3150/11-BEJ406

Abstract

We develop a new formulation of Stein’s method to obtain computable upper bounds on the total variation distance between the geometric distribution and a distribution of interest. Our framework reduces the problem to the construction of a coupling between the original distribution and the “discrete equilibrium” distribution from renewal theory. We illustrate the approach in four non-trivial examples: the geometric sum of independent, non-negative, integer-valued random variables having common mean, the generation size of the critical Galton–Watson process conditioned on non-extinction, the in-degree of a randomly chosen node in the uniform attachment random graph model and the total degree of both a fixed and randomly chosen node in the preferential attachment random graph model.

Citation

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Erol A. Peköz. Adrian Röllin. Nathan Ross. "Total variation error bounds for geometric approximation." Bernoulli 19 (2) 610 - 632, May 2013. https://doi.org/10.3150/11-BEJ406

Information

Published: May 2013
First available in Project Euclid: 13 March 2013

zbMATH: 06168765
MathSciNet: MR3037166
Digital Object Identifier: 10.3150/11-BEJ406

Keywords: discrete equilibrium distribution , geometric distribution , Preferential attachment model , Stein’s method , Yaglom’s theorem

Rights: Copyright © 2013 Bernoulli Society for Mathematical Statistics and Probability

Vol.19 • No. 2 • May 2013
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