Your search keyword '"Dong, Zhongtian"' showing total 3 results

1. The LHC Olympics 2020 a community challenge for anomaly detection in high energy physics.

Author

Kasieczka G, Nachman B, Shih D, Amram O, Andreassen A, Benkendorfer K, Bortolato B, Brooijmans G, Canelli F, Collins JH, Dai B, De Freitas FF, Dillon BM, Dinu IM, Dong Z, Donini J, Duarte J, Faroughy DA, Gonski J, Harris P, Kahn A, Kamenik JF, Khosa CK, Komiske P, Le Pottier L, Martín-Ramiro P, Matevc A, Metodiev E, Mikuni V, Murphy CW, Ochoa I, Park SE, Pierini M, Rankin D, Sanz V, Sarda N, Seljak U, Smolkovic A, Stein G, Suarez CM, Szewc M, Thaler J, Tsan S, Udrescu SM, Vaslin L, Vlimant JR, Williams D, and Yunus M

Subjects

Humans, Physical Phenomena, Physics, Machine Learning, Supervised Machine Learning

Abstract

A new paradigm for data-driven, model-agnostic new physics searches at colliders is emerging, and aims to leverage recent breakthroughs in anomaly detection and machine learning. In order to develop and benchmark new anomaly detection methods within this framework, it is essential to have standard datasets. To this end, we have created the LHC Olympics 2020, a community challenge accompanied by a set of simulated collider events. Participants in these Olympics have developed their methods using an R&D dataset and then tested them on black boxes: datasets with an unknown anomaly (or not). Methods made use of modern machine learning tools and were based on unsupervised learning (autoencoders, generative adversarial networks, normalizing flows), weakly supervised learning, and semi-supervised learning. This paper will review the LHC Olympics 2020 challenge, including an overview of the competition, a description of methods deployed in the competition, lessons learned from the experience, and implications for data analyses with future datasets as well as future colliders., (© 2021 IOP Publishing Ltd.)

Published

2021

2. A Comparison between Invariant and Equivariant Classical and Quantum Graph Neural Networks.

Author

Forestano, Roy T., Comajoan Cara, Marçal, Dahale, Gopal Ramesh, Dong, Zhongtian, Gleyzer, Sergei, Justice, Daniel, Kong, Kyoungchul, Magorsch, Tom, Matchev, Konstantin T., Matcheva, Katia, and Unlu, Eyup B.

Subjects

GRAPH neural networks, QUANTUM graph theory, MACHINE learning, LARGE Hadron Collider, COLLISIONS (Nuclear physics)

Abstract

Machine learning algorithms are heavily relied on to understand the vast amounts of data from high-energy particle collisions at the CERN Large Hadron Collider (LHC). The data from such collision events can naturally be represented with graph structures. Therefore, deep geometric methods, such as graph neural networks (GNNs), have been leveraged for various data analysis tasks in high-energy physics. One typical task is jet tagging, where jets are viewed as point clouds with distinct features and edge connections between their constituent particles. The increasing size and complexity of the LHC particle datasets, as well as the computational models used for their analysis, have greatly motivated the development of alternative fast and efficient computational paradigms such as quantum computation. In addition, to enhance the validity and robustness of deep networks, we can leverage the fundamental symmetries present in the data through the use of invariant inputs and equivariant layers. In this paper, we provide a fair and comprehensive comparison of classical graph neural networks (GNNs) and equivariant graph neural networks (EGNNs) and their quantum counterparts: quantum graph neural networks (QGNNs) and equivariant quantum graph neural networks (EQGNN). The four architectures were benchmarked on a binary classification task to classify the parton-level particle initiating the jet. Based on their area under the curve (AUC) scores, the quantum networks were found to outperform the classical networks. However, seeing the computational advantage of quantum networks in practice may have to wait for the further development of quantum technology and its associated application programming interfaces (APIs). [ABSTRACT FROM AUTHOR]

Published

2024

3. Snowmass 2021 Computational Frontier CompF03 Topical Group Report: Machine Learning

Author

Shanahan, Phiala, Terao, Kazuhiro, Whiteson, Daniel, Aarts, Gert, Adelmann, Andreas, Akchurin, N., Alexandru, Andrei, Amram, Oz, Andreassen, Anders, Apresyan, Artur, Avestruz, Camille, Bartoldus, Rainer, Bechtol, Keith, Benkendorfer, Kees, Benelli, Gabriele, Bernius, Catrin, Bogatskiy, Alexander, Bortolato, Blaz, Boyda, Denis, Brooijmans, Gustaaf, Calafiura, Paolo, Calì, Salvatore, Canelli, Florencia, Chachamis, Grigorios, Chekanov, S. V., Chen, Deming, Chen, Thomas Y., Ćiprijanović, Aleksandra, Collins, Jack H., Connolly, J. Andrew, Coughlin, Michael, Dai, Biwei, Damgov, J., Dezoort, Gage, Diaz, Daniel, Dillon, Barry M., Dinu, Ioan-Mihail, Dong, Zhongtian, Donini, Julien, Duarte, Javier, Dugad, S., Dvorkin, Cora, Faroughy, D. A., Feickert, Matthew, Feng, Yongbin, Fenton, Michael, Foreman, Sam, Freitas, Felipe F., Lena Funcke, C, P. G., Gandrakota, Abhijith, Ganguly, Sanmay, Garrison, Lehman H., Gessner, Spencer, Ghosh, Aishik, Gonsk, Julia, Graham, Matthew, Gray, Lindsey, Grönroos, S., Hackett, Daniel C., Harris, Philip, Hauck, Scott, Herwig, Christian, Holzman, Burt, Hopkins, Walter, Hsu, Shih-Chieh, Huang, Jin, Huang, Yi, Jin, Xiao-Yong, Kagan, Michael, Kah, Alan, Kamenik, Jernej F., Kansal, Raghav, Karagiorgi, Georgia, Kasieczka, Gregor, Katsavounidis, Erik, Khoda, Elham E., Khosa, Charanjit K., Kipf, Thomas, Komiske, Patrick, Komm, Matthias, Kondor, Risi, Kourlitis, Evangelos, Krause, Claudius, Lamichhane, K., Le Pottier, Luc, Lin, Meifeng, Lin, Yin, Liu, Mia, Lu, Nan, Lucini, Biagio, Martinez, J., Martín-Ramiro, Pablo, Matevc, Andrej, Mccormack, William Patrick, Metodiev, Eric, Mikuni, Vinicius, Miller, David W., Mishra-Sharma, Siddharth, Mukherjee, Samadrita, Murnane, Daniel, Nachman, Benjamin, Narayan, Gautham, Neubauer, Mark, Ngadiuba, Jennifer, Norberg, Scarlet, Nord, Brian, Ochoa, Inês, Offermann, Jan T., Park, Sang Eon, Pedro, Kevin, Peña, Cristían, Perloff, Alexx, Pettee, Mariel, Pierini, Maurizio, Quast, T., Rankin, Dylan, Ren, Yihui, Rieger, Marcel, Vlimant, Jean-Roch, Roy, Avik, Sanz, Veronica, Sarda, Nilai, Savard, Claire, Scheinker, Alexander, Uros, Seljak, Sheldon, Brian, Shih, David, Shimmin, Chase, Smolkovic, Aleks, Stein, George, Mantilla Suarez, Cristina, Szewc, Manuel, Thais, Savannah, Thaler, Jesse, Torbunov, Dmitrii, Tran, Nhan, Tsan, Steven, Udrescu, Silviu-Marian, Undleeb, S., Vaslin, Louis, Villaescusa-Navarro, Francisco, Villar, V. Ashley, Viren, Brett, Whitbeck, A., Williams, Daniel, Winklehner, Daniel, Xie, Si, Yang, Tingjun, Yu, Haiwang, Yunus, Mikaeel, Laboratoire de Physique de Clermont (LPC), and Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Centre National de la Recherche Scientifique (CNRS)-Université Clermont Auvergne (UCA)

Subjects

High Energy Physics - Theory, FOS: Computer and information sciences, Computer Science - Artificial Intelligence, Other Fields of Physics, FOS: Physical sciences, hep-lat, programming, High Energy Physics - Experiment, High Energy Physics - Experiment (hep-ex), High Energy Physics - Lattice, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], [INFO]Computer Science [cs], activity report, [PHYS.HLAT]Physics [physics]/High Energy Physics - Lattice [hep-lat], [PHYS.HTHE]Physics [physics]/High Energy Physics - Theory [hep-th], hep-ex, hep-th, High Energy Physics - Lattice (hep-lat), Particle Physics - Lattice, Computational Physics (physics.comp-ph), cs.AI, Computing and Computers, machine learning, Artificial Intelligence (cs.AI), High Energy Physics - Theory (hep-th), physics.comp-ph, Physics - Computational Physics, Particle Physics - Theory, Particle Physics - Experiment

Abstract

The rapidly-developing intersection of machine learning (ML) with high-energy physics (HEP) presents both opportunities and challenges to our community. Far beyond applications of standard ML tools to HEP problems, genuinely new and potentially revolutionary approaches are being developed by a generation of talent literate in both fields. There is an urgent need to support the needs of the interdisciplinary community driving these developments, including funding dedicated research at the intersection of the two fields, investing in high-performance computing at universities and tailoring allocation policies to support this work, developing of community tools and standards, and providing education and career paths for young researchers attracted by the intellectual vitality of machine learning for high energy physics., Comment: Contribution to Snowmass 2021