arXiv : Learning New Physics from a Machine

D'Agnolo, Raffaele Tito; Wulzer, Andrea

doi:10.1103/PhysRevD.99.015014

Article
Report number	arXiv:1806.02350
Title	Learning New Physics from a Machine
Author(s)	D'Agnolo, Raffaele Tito (SLAC) ; Wulzer, Andrea (CERN ; ITPP, Lausanne ; INFN, Padua ; Padua U.)
Publication	2019-01-08
Imprint	2018-06-06
Number of pages	20
Note	28 pages, 11 figures
In:	Phys. Rev. D 99 (2019) 015014
DOI	10.1103/PhysRevD.99.015014
Subject category	physics.comp-ph ; Other Fields of Physics ; hep-ex ; Particle Physics - Experiment ; hep-ph ; Particle Physics - Phenomenology
Abstract	We propose using neural networks to detect data departures from a given reference model, with no prior bias on the nature of the new physics responsible for the discrepancy. The virtues of neural networks as unbiased function approximants make them particularly suited for this task. An algorithm that implements this idea is constructed, as a straightforward application of the likelihood-ratio hypothesis test. The algorithm compares observations with an auxiliary set of reference-distributed events, possibly obtained with a Monte Carlo event generator. It returns a p-value, which measures the compatibility of the reference model with the data. It also identifies the most discrepant phase-space region of the data set, to be selected for further investigation. The most interesting potential applications are model-independent new physics searches, although our approach could also be used to compare the theoretical predictions of different Monte Carlo event generators, or for data validation algorithms. In this work we study the performance of our algorithm on a few simple examples. The results confirm the model-independence of the approach, namely that it displays good sensitivity to a variety of putative signals. Furthermore, we show that the reach does not depend much on whether a favorable signal region is selected based on prior expectations. We identify directions for improvement towards applications to real experimental data sets.
Copyright/License	preprint: (License: arXiv nonexclusive-distrib 1.0) Publication: © 2019-2025 authors

$Illustration of how three-neurons with logistic sigmoid activation functions can reproduce a rectangular function or a smooth peak. The parameters in the legend of the plot are defined in Eq.s~(\ref{eq:nn1}) and (\ref{eq:nn2}).$

${\it Left panel}: Test statistic distribution in the reference hypothesis, $P(t|R)$, for networks with one hidden layer and $3, 4$ or $10$ neurons, compared to the $\chi^2$ with the same number of d.o.f. as the network. The training parameters are the same for all architectures (15000 training rounds, $0.001$ initial learning rate, \textsc{RMSprop} algorithm). {\it Right panel}: Test statistic distribution in the reference hypothesis for the network architecture with 10 neurons. We compare the result with 150 thousands and 1.5 million training rounds. The figure shows how our networks reproduce the asymptotic formulas for the test statistic expected from the theorems in~\cite{Wilks:1938dza, Wald1943}. However larger networks require more training rounds.$ Show more plots

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Record created 2018-06-28, last modified 2023-12-13

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