Machine Learning Methods for Multiscale Physics and Urban Engineering Problems

Somya Sharma; Marten Thompson; Debra Laefer; Michael Lawler; Kevin McIlhany; Olivier Pauluis; Dallas R. Trinkle; Snigdhansu Chatterjee

doi:10.3390/e24081134

Machine Learning Methods for Multiscale Physics and Urban Engineering Problems

Somya Sharma, Marten Thompson, Debra Laefer, Michael Lawler, Kevin McIlhany, Olivier Pauluis, Dallas R. Trinkle, Snigdhansu Chatterjee

Statistics (Twin Cities)

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Abstract

We present an overview of four challenging research areas in multiscale physics and engineering as well as four data science topics that may be developed for addressing these challenges. We focus on multiscale spatiotemporal problems in light of the importance of understanding the accompanying scientific processes and engineering ideas, where “multiscale” refers to concurrent, non-trivial and coupled models over scales separated by orders of magnitude in either space, time, energy, momenta, or any other relevant parameter. Specifically, we consider problems where the data may be obtained at various resolutions; analyzing such data and constructing coupled models led to open research questions in various applications of data science. Numeric studies are reported for one of the data science techniques discussed here for illustration, namely, on approximate Bayesian computations.

Original language	English (US)
Article number	1134
Journal	Entropy
Volume	24
Issue number	8
DOIs	https://doi.org/10.3390/e24081134
State	Published - Aug 2022

Bibliographical note

Funding Information:
This research is partially supported by the US National Science Foundation (NSF) under grants 1737918, 1939916, 1939956, 1940145, 1940260, 1940287, and a grant from Cisco Systems Inc.

Publisher Copyright:
© 2022 by the authors.

Keywords

approximate Bayesian computation
approximate Hamiltonian
dimension reduction
hybrid approach
moist atmosphere dynamics
molecular dynamics
multi-resolution Gaussian Process
spin ice
time evolution
urban engineering

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abstract = "We present an overview of four challenging research areas in multiscale physics and engineering as well as four data science topics that may be developed for addressing these challenges. We focus on multiscale spatiotemporal problems in light of the importance of understanding the accompanying scientific processes and engineering ideas, where “multiscale” refers to concurrent, non-trivial and coupled models over scales separated by orders of magnitude in either space, time, energy, momenta, or any other relevant parameter. Specifically, we consider problems where the data may be obtained at various resolutions; analyzing such data and constructing coupled models led to open research questions in various applications of data science. Numeric studies are reported for one of the data science techniques discussed here for illustration, namely, on approximate Bayesian computations.",

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AU - Trinkle, Dallas R.

AU - Chatterjee, Snigdhansu

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Machine Learning Methods for Multiscale Physics and Urban Engineering Problems

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Keywords

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