CERN Accelerating science

ATLAS Slides
Report number ATL-SOFT-SLIDE-2024-613
Title Overcoming challenges of quantum interference at LHC with neural simulation-based inference and a full implementation in ATLAS
Author(s) Ghosh, Aishik (University of California Irvine (US))
Corporate author(s) The ATLAS collaboration
Collaboration ATLAS Collaboration
Submitted by [email protected] on 04 Dec 2024
Subject category Particle Physics - Experiment
Accelerator/Facility, Experiment CERN LHC ; ATLAS
Free keywords neural simulation-based inference ; high-dimensional statistics ; Higgs width ; off-shell Higgs ; quantum interference
Abstract Quantum interference between signal and background Feynman diagrams produce non-linear effects that challenge core assumptions going into the statistical analysis methodology in particle physics. I show that for such cases, no single observable can capture all the relevant information needed to perform optimal inference of theory parameters from data collected in our experiments. The optimal data analysis strategy is to perform statistical inference directly on high-dimensional data, without relying on summary histograms. Neural Simulation-Based Inference (NSBI) is a class of techniques that naturally handle high dimensional data, avoiding the need to design low-dimensional summary histograms. We design a general purpose statistical framework in the ATLAS experiment that enables the application of NSBI to a full-scale physics analysis, leading to the most precise measurement of the Higgs width by the experiment to date. This work develops several innovative solutions to introduce uncertainty quantification and enhance robustness and interpretability in NSBI. The developed method is an extension of the standard frequentist statistical inference framework used in particle physics and is therefore applicable to a wide range of physics analysis.



 Záznam vytvorený 2024-12-04, zmenený 2024-12-04