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Main Author: Semkow, Thomas M.
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2312.03894
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author Semkow, Thomas M.
author_facet Semkow, Thomas M.
contents We developed a statistical theory of zero-count-detector (ZCD), which is defined as a zero-class Poisson under conditions outlined in the paper. ZCD is often encountered in the studies of rare events in physics, health physics, and many other fields where counting of events occurs. We found no acceptable solution to ZCD in classical statistics and affirmed the need for the Bayesian statistics. Several uniform and reference priors were studied and we derived Bayesian posteriors, point estimates, and upper limits. It was showed that the maximum-entropy prior, containing the most information, resulted in the smallest bias and the lowest risk, making it the most admissible and acceptable among the priors studied. We also investigated application of zero-inflated Poisson and Negative-binomial distributions to ZCD. It was showed using Bayesian marginalization that, under limited information, these distributions reduce to the Poisson distribution.
format Preprint
id arxiv_https___arxiv_org_abs_2312_03894
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Zero-Class Poisson for Rare-Event Studies
Semkow, Thomas M.
Applications
Mathematical Physics
Nuclear Experiment
We developed a statistical theory of zero-count-detector (ZCD), which is defined as a zero-class Poisson under conditions outlined in the paper. ZCD is often encountered in the studies of rare events in physics, health physics, and many other fields where counting of events occurs. We found no acceptable solution to ZCD in classical statistics and affirmed the need for the Bayesian statistics. Several uniform and reference priors were studied and we derived Bayesian posteriors, point estimates, and upper limits. It was showed that the maximum-entropy prior, containing the most information, resulted in the smallest bias and the lowest risk, making it the most admissible and acceptable among the priors studied. We also investigated application of zero-inflated Poisson and Negative-binomial distributions to ZCD. It was showed using Bayesian marginalization that, under limited information, these distributions reduce to the Poisson distribution.
title Zero-Class Poisson for Rare-Event Studies
topic Applications
Mathematical Physics
Nuclear Experiment
url https://arxiv.org/abs/2312.03894