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Main Authors: Grosso, Gaia, Letizia, Marco, Pierini, Maurizio, Wulzer, Andrea
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2305.14137
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author Grosso, Gaia
Letizia, Marco
Pierini, Maurizio
Wulzer, Andrea
author_facet Grosso, Gaia
Letizia, Marco
Pierini, Maurizio
Wulzer, Andrea
contents The Neyman-Pearson strategy for hypothesis testing can be employed for goodness of fit if the alternative hypothesis is selected from data by exploring a rich parametrised family of models, while controlling the impact of statistical fluctuations. The New Physics Learning Machine (NPLM) methodology has been developed as a concrete implementation of this idea, to target the detection of new physical effects in the context of high energy physics collider experiments. In this paper we conduct a comparison of this approach to goodness of fit with others, in particular with classifier-based strategies that share strong similarities with NPLM. From our comparison, NPLM emerges as the more sensitive test to small departures of the data from the expected distribution and not biased towards detecting specific types of anomalies. These features make it suited for agnostic searches for new physics at collider experiments. Its deployment in other scientific and industrial scenarios should be investigated.
format Preprint
id arxiv_https___arxiv_org_abs_2305_14137
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Goodness of fit by Neyman-Pearson testing
Grosso, Gaia
Letizia, Marco
Pierini, Maurizio
Wulzer, Andrea
High Energy Physics - Phenomenology
Machine Learning
The Neyman-Pearson strategy for hypothesis testing can be employed for goodness of fit if the alternative hypothesis is selected from data by exploring a rich parametrised family of models, while controlling the impact of statistical fluctuations. The New Physics Learning Machine (NPLM) methodology has been developed as a concrete implementation of this idea, to target the detection of new physical effects in the context of high energy physics collider experiments. In this paper we conduct a comparison of this approach to goodness of fit with others, in particular with classifier-based strategies that share strong similarities with NPLM. From our comparison, NPLM emerges as the more sensitive test to small departures of the data from the expected distribution and not biased towards detecting specific types of anomalies. These features make it suited for agnostic searches for new physics at collider experiments. Its deployment in other scientific and industrial scenarios should be investigated.
title Goodness of fit by Neyman-Pearson testing
topic High Energy Physics - Phenomenology
Machine Learning
url https://arxiv.org/abs/2305.14137