Machine learning of hidden variables in multiscale fluid simulation
Solving fluid dynamics equations often requires the use of closure relations that account for missing microphysics. For example, when solving equations related to fluid dynamics for systems with a large Reynolds number, sub-grid effects become important and a turbulence closure is required, and in s...
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| creator | Joglekar, Archis S Thomas, Alexander G. R |
| description | Solving fluid dynamics equations often requires the use of closure relations
that account for missing microphysics. For example, when solving equations
related to fluid dynamics for systems with a large Reynolds number, sub-grid
effects become important and a turbulence closure is required, and in systems
with a large Knudsen number, kinetic effects become important and a kinetic
closure is required. By adding an equation governing the growth and transport
of the quantity requiring the closure relation, it becomes possible to capture
microphysics through the introduction of ``hidden variables'' that are
non-local in space and time. The behavior of the ``hidden variables'' in
response to the fluid conditions can be learned from a higher fidelity or
ab-initio model that contains all the microphysics. In our study, a partial
differential equation simulator that is end-to-end differentiable is used to
train judiciously placed neural networks against ground-truth simulations. We
show that this method enables an Euler equation based approach to reproduce
non-linear, large Knudsen number plasma physics that can otherwise only be
modeled using Boltzmann-like equation simulators such as Vlasov or
Particle-In-Cell modeling. |
| doi_str_mv | 10.48550/arxiv.2306.10709 |
| format | Article |
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that account for missing microphysics. For example, when solving equations
related to fluid dynamics for systems with a large Reynolds number, sub-grid
effects become important and a turbulence closure is required, and in systems
with a large Knudsen number, kinetic effects become important and a kinetic
closure is required. By adding an equation governing the growth and transport
of the quantity requiring the closure relation, it becomes possible to capture
microphysics through the introduction of ``hidden variables'' that are
non-local in space and time. The behavior of the ``hidden variables'' in
response to the fluid conditions can be learned from a higher fidelity or
ab-initio model that contains all the microphysics. In our study, a partial
differential equation simulator that is end-to-end differentiable is used to
train judiciously placed neural networks against ground-truth simulations. We
show that this method enables an Euler equation based approach to reproduce
non-linear, large Knudsen number plasma physics that can otherwise only be
modeled using Boltzmann-like equation simulators such as Vlasov or
Particle-In-Cell modeling.</description><identifier>DOI: 10.48550/arxiv.2306.10709</identifier><language>eng</language><subject>Computer Science - Artificial Intelligence ; Computer Science - Numerical Analysis ; Mathematics - Numerical Analysis ; Physics - Computational Physics ; Physics - Fluid Dynamics ; Physics - Plasma Physics</subject><creationdate>2023-06</creationdate><rights>http://creativecommons.org/licenses/by/4.0</rights><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>228,230,780,885</link.rule.ids><linktorsrc>$$Uhttps://arxiv.org/abs/2306.10709$$EView_record_in_Cornell_University$$FView_record_in_$$GCornell_University$$Hfree_for_read</linktorsrc><backlink>$$Uhttps://doi.org/10.48550/arXiv.2306.10709$$DView paper in arXiv$$Hfree_for_read</backlink></links><search><creatorcontrib>Joglekar, Archis S</creatorcontrib><creatorcontrib>Thomas, Alexander G. R</creatorcontrib><title>Machine learning of hidden variables in multiscale fluid simulation</title><description>Solving fluid dynamics equations often requires the use of closure relations
that account for missing microphysics. For example, when solving equations
related to fluid dynamics for systems with a large Reynolds number, sub-grid
effects become important and a turbulence closure is required, and in systems
with a large Knudsen number, kinetic effects become important and a kinetic
closure is required. By adding an equation governing the growth and transport
of the quantity requiring the closure relation, it becomes possible to capture
microphysics through the introduction of ``hidden variables'' that are
non-local in space and time. The behavior of the ``hidden variables'' in
response to the fluid conditions can be learned from a higher fidelity or
ab-initio model that contains all the microphysics. In our study, a partial
differential equation simulator that is end-to-end differentiable is used to
train judiciously placed neural networks against ground-truth simulations. We
show that this method enables an Euler equation based approach to reproduce
non-linear, large Knudsen number plasma physics that can otherwise only be
modeled using Boltzmann-like equation simulators such as Vlasov or
Particle-In-Cell modeling.</description><subject>Computer Science - Artificial Intelligence</subject><subject>Computer Science - Numerical Analysis</subject><subject>Mathematics - Numerical Analysis</subject><subject>Physics - Computational Physics</subject><subject>Physics - Fluid Dynamics</subject><subject>Physics - Plasma Physics</subject><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2023</creationdate><recordtype>article</recordtype><sourceid>GOX</sourceid><recordid>eNotj81OwzAQhH3hgFoegBN-gQSnGzvxsYr4k4p66T1a22u6kusip63g7QmFy4w0oxnpE-K-UXXba60esXzxpV6BMnWjOmVvxfCOfs-ZZCIsmfOHPEa55xAoywsWRpdokpzl4ZxOPHlMJGM6c5ATzxGe-JiX4iZimuju3xdi9_y0G16rzfblbVhvKjSdraDvYuO114q8iQFdsAC-1cZrbUPoW3BkaC6sgda5WRECqJXWgeK8gYV4-Lu9UoyfhQ9YvsdfmvFKAz9xNkYk</recordid><startdate>20230619</startdate><enddate>20230619</enddate><creator>Joglekar, Archis S</creator><creator>Thomas, Alexander G. R</creator><scope>AKY</scope><scope>AKZ</scope><scope>GOX</scope></search><sort><creationdate>20230619</creationdate><title>Machine learning of hidden variables in multiscale fluid simulation</title><author>Joglekar, Archis S ; Thomas, Alexander G. R</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-a679-387f1c5c50ec6fdabd933c456c559dd843be6efda9634bb963a3d30255def0ec3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2023</creationdate><topic>Computer Science - Artificial Intelligence</topic><topic>Computer Science - Numerical Analysis</topic><topic>Mathematics - Numerical Analysis</topic><topic>Physics - Computational Physics</topic><topic>Physics - Fluid Dynamics</topic><topic>Physics - Plasma Physics</topic><toplevel>online_resources</toplevel><creatorcontrib>Joglekar, Archis S</creatorcontrib><creatorcontrib>Thomas, Alexander G. R</creatorcontrib><collection>arXiv Computer Science</collection><collection>arXiv Mathematics</collection><collection>arXiv.org</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Joglekar, Archis S</au><au>Thomas, Alexander G. R</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Machine learning of hidden variables in multiscale fluid simulation</atitle><date>2023-06-19</date><risdate>2023</risdate><abstract>Solving fluid dynamics equations often requires the use of closure relations
that account for missing microphysics. For example, when solving equations
related to fluid dynamics for systems with a large Reynolds number, sub-grid
effects become important and a turbulence closure is required, and in systems
with a large Knudsen number, kinetic effects become important and a kinetic
closure is required. By adding an equation governing the growth and transport
of the quantity requiring the closure relation, it becomes possible to capture
microphysics through the introduction of ``hidden variables'' that are
non-local in space and time. The behavior of the ``hidden variables'' in
response to the fluid conditions can be learned from a higher fidelity or
ab-initio model that contains all the microphysics. In our study, a partial
differential equation simulator that is end-to-end differentiable is used to
train judiciously placed neural networks against ground-truth simulations. We
show that this method enables an Euler equation based approach to reproduce
non-linear, large Knudsen number plasma physics that can otherwise only be
modeled using Boltzmann-like equation simulators such as Vlasov or
Particle-In-Cell modeling.</abstract><doi>10.48550/arxiv.2306.10709</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Computer Science - Artificial Intelligence Computer Science - Numerical Analysis Mathematics - Numerical Analysis Physics - Computational Physics Physics - Fluid Dynamics Physics - Plasma Physics |
| title | Machine learning of hidden variables in multiscale fluid simulation |
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