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
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
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