Parameter Estimation of Mechanistic Differential Equations via Neural Differential Equations

Bradley, William; Boukouvala, Fani

Title:

Parameter Estimation of Mechanistic Differential Equations via Neural Differential Equations

dc.contributor.author	Bradley, William
dc.contributor.author	Boukouvala, Fani
dc.contributor.corporatename	Georgia Institute of Technology. Professional Education	en_US
dc.contributor.corporatename	Georgia Institute of Technology. Office of the Vice Provost for Graduate Education and Faculty Development	en_US
dc.contributor.corporatename	Georgia Institute of Technology. Center for Career Discovery and Development	en_US
dc.contributor.corporatename	Georgia Institute of Technology. Office of Graduate Studies	en_US
dc.contributor.corporatename	Georgia Institute of Technology. Student Government Association	en_US
dc.contributor.corporatename	Georgia Institute of Technology. School of Chemical and Biomolecular Engineering	en_US
dc.date.accessioned	2021-03-17T15:55:38Z
dc.date.available	2021-03-17T15:55:38Z
dc.date.issued	2021
dc.description	Presented at the Georgia Tech Career, Research and Innovation Development Conference. 2021. Atlanta, GA	en_US
dc.description.abstract	Persisting trends of increased data availability and refined user-friendly tools to model large datasets has encouraged renewed interest in constructing data-driven models to solve real-world problems, with much success. In particular, Neural Ordinary Differential Equations (Neural ODEs) have recently demonstrated the ability to interpolate dynamic data of arbitrary nonlinearity. However, data-driven models are often cursed with limited interpretability and fail to obey physical laws governing many engineering and scientific applications. Alternatively, mechanistic models, which use prior knowledge based on physical laws or domain expertise, often require less data and observe better extrapolation performance, significantly reducing the experimental overhead to track system relationships. However, building mechanistic models may become computationally intractable when the model’s differential equations are strongly nonlinear or a good initial guess for the parameter values is unavailable. This work demonstrates how Neural ODEs can be used as a data-driven means to a mechanistic end—namely, estimating the parameter values in mechanistic differential equations. Using a 2-stage, or indirect, approach the Neural ODE can be trained to accurately estimate the derivative profiles of the system states. Then in the second step, the derivative and state estimates of the Neural ODE can be used to estimate the parameters of the original mechanistic model. In this presentation, the performance of the Neural ODE approach is characterized for scenarios of varying measurement noise and mechanistic model nonlinearity. Moreover, we compare the proposed Neural ODE approach with traditional direct approaches to regress differential equation models for examples ranging from ecology to chemical engineering.	en_US
dc.description.sponsorship	RAPID/NNMI Grant #GR10002225; Georgia Tech start-up grant and NSF CBET grants (1336386 and 1944678)	en_US
dc.identifier.uri	http://hdl.handle.net/1853/64387
dc.language.iso	en_US	en_US
dc.publisher	Georgia Institute of Technology	en_US
dc.relation.ispartofseries	CRIDC
dc.subject	Neural ODEs	en_US
dc.subject	2-stage Approach	en_US
dc.subject	Extrapolation	en_US
dc.subject	Time series modeling	en_US
dc.title	Parameter Estimation of Mechanistic Differential Equations via Neural Differential Equations	en_US
dc.type	Text
dc.type.genre	Poster
dspace.entity.type	Publication
local.contributor.author	Boukouvala, Fani
local.contributor.corporatename	Office of Graduate Education
local.relation.ispartofseries	Career, Research, and Innovation Development Conference
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