04058nam 22006135 450 99650357020331620230103011142.03-11-078596-X10.1515/9783110785968(CKB)5580000000492179(DE-B1597)617926(DE-B1597)9783110785968(MiAaPQ)EBC7156399(Au-PeEL)EBL7156399(OCoLC)1356978797(EXLCZ)99558000000049217920230103h20222023 fg engur|||||||||||txtrdacontentcrdamediacrrdacarrierMachine Learning under Resource Constraints. Discovery in Physics /ed. by Katharina Morik, Wolfgang Rhode1st ed.Berlin ;Boston : De Gruyter, [2022]©20231 online resource (XIV, 349 p.)De Gruyter STEM ;Volume 23-11-078595-1 Frontmatter -- Contents -- 1 Introduction -- 2 Challenges in Particle and Astroparticle Physics -- 3 Key Concepts in Machine Learning and Data Analysis -- 4 Data Acquisition and Data Structure -- 5 Monte Carlo Simulations -- 6 Data Storage and Access -- 7 Monitoring and Feature Extraction -- 8 Event Property Estimation and Signal Background Separation -- 9 Deep Learning Applications -- 10 Inverse Problems -- Bibliography -- Index -- List of ContributorsMachine Learning under Resource Constraints addresses novel machine learning algorithms that are challenged by high-throughput data, by high dimensions, or by complex structures of the data in three volumes. Resource constraints are given by the relation between the demands for processing the data and the capacity of the computing machinery. The resources are runtime, memory, communication, and energy. Hence, modern computer architectures play a significant role. Novel machine learning algorithms are optimized with regard to minimal resource consumption. Moreover, learned predictions are executed on diverse architectures to save resources. It provides a comprehensive overview of the novel approaches to machine learning research that consider resource constraints, as well as the application of the described methods in various domains of science and engineering. Volume 2 covers machine learning for knowledge discovery in particle and astroparticle physics. Their instruments, e.g., particle detectors or telescopes, gather petabytes of data. Here, machine learning is necessary not only to process the vast amounts of data and to detect the relevant examples efficiently, but also as part of the knowledge discovery process itself. The physical knowledge is encoded in simulations that are used to train the machine learning models. At the same time, the interpretation of the learned models serves to expand the physical knowledge. This results in a cycle of theory enhancement supported by machine learning.De Gruyter STEM SeriesSCIENCE / Chemistry / GeneralbisacshArtificial Intelligence.Big Data and Machine Learning.Cyber-physical systems.Data mining for Ubiquitous System Software.Embedded Systems and Machine Learning.Highly Distributed Data.ML on Small devices.Machine learning for knowledge discovery.Machine learning in high-energy physics.Resource-Aware Machine Learning.Resource-Constrained Data Analysis.SCIENCE / Chemistry / General.006.31Morik Katharina, edthttp://id.loc.gov/vocabulary/relators/edtRhode Wolfgang, edthttp://id.loc.gov/vocabulary/relators/edtDE-B1597DE-B1597BOOK996503570203316Machine Learning under Resource Constraints3011774UNISA