Learning new physics from an imperfect machine
TL;DR: In this article , the authors show how to deal with uncertainties on the Standard Model predictions in an agnostic new physics search strategy that exploits artificial neural networks, based on the specific Maximum Likelihood ratio treatment of uncertainties as nuisance parameters for hypothesis testing that is routinely employed in high-energy physics.
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Abstract: Abstract We show how to deal with uncertainties on the Standard Model predictions in an agnostic new physics search strategy that exploits artificial neural networks. Our approach builds directly on the specific Maximum Likelihood ratio treatment of uncertainties as nuisance parameters for hypothesis testing that is routinely employed in high-energy physics. After presenting the conceptual foundations of our method, we first illustrate all aspects of its implementation and extensively study its performances on a toy one-dimensional problem. We then show how to implement it in a multivariate setup by studying the impact of two typical sources of experimental uncertainties in two-body final states at the LHC.
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Citations
Improving Variational Autoencoders for New Physics Detection at the LHC With Normalizing Flows
TL;DR: In this article , the authors investigate how to improve new physics detection strategies exploiting variational autoencoders and normalizing flows for anomaly detection at the Large Hadron Collider, and show how different design choices (e.g., event representations, anomaly score definitions, network architectures) affect the result on specific benchmark new physics models.
Learning new physics from an imperfect machine
TL;DR: In this article , the authors show how to deal with uncertainties on the Standard Model predictions in an agnostic new physics search strategy that exploits artificial neural networks, based on the specific Maximum Likelihood ratio treatment of uncertainties as nuisance parameters for hypothesis testing that is routinely employed in high-energy physics.
Self-supervised anomaly detection for new physics
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TL;DR: In this article , the authors train a transformer neural network to encode simulated QCD "event space" dijets into a low-dimensional "latent space" representation and optimize the network using the self-supervised contrastive loss.
23
Leveraging universality of jet taggers through transfer learning
Frédéric A. Dreyer,Radoslaw Grabarczyk,Pier Francesco Monni +2 more
- 11 Mar 2022
TL;DR: In this article , transfer learning techniques were used to develop fast and data-efficient jet taggers that leverage the universality of QCD signals and experimental setups. But the authors only considered the graph neural networks (LundNet and ParticleNet).
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Unbinned multivariate observables for global SMEFT analyses from machine learning
TL;DR: The ML4EFT framework as discussed by the authors combines machine learning regression and classification techniques to parameterize high-dimensional likelihood ratios, using the Monte Carlo replica method to estimate and propagate methodological uncertainties.
References
Anomaly detection: A survey
TL;DR: This survey tries to provide a structured and comprehensive overview of the research on anomaly detection by grouping existing techniques into different categories based on the underlying approach adopted by each technique.
PYTHIA 6.4 Physics and Manual
TL;DR: The Pythia program as mentioned in this paper can be used to generate high-energy-physics ''events'' (i.e. sets of outgoing particles produced in the interactions between two incoming particles).
The automated computation of tree-level and next-to-leading order differential cross sections, and their matching to parton shower simulations
Johan Alwall,Rikkert Frederix,Stefano Frixione,Valentin Hirschi,Fabio Maltoni,Olivier Mattelaer,Hua-Sheng Shao,Tim Stelzer,Paolo Torrielli,Marco Zaro,Marco Zaro +10 more
TL;DR: MadGraph5 aMC@NLO as discussed by the authors is a computer program capable of handling all these computations, including parton-level fixed order, shower-matched, merged, in a unified framework whose defining features are flexibility, high level of parallelisation and human intervention limited to input physics quantities.
Oxford University Press : Review of Particle Physics, 2020-2021
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