Probabilistic gradients for fast calibration of differential equation models
Probabilistic gradients for fast calibration of differential equation models
Calibration of large-scale differential equation models to observational or experimental data is a widespread challenge throughout applied sciences and engineering. A crucial bottleneck in state-of-the art calibration methods is the calculation of local sensitivities, i.e. derivatives of the loss function with respect to the estimated parameters, which often necessitates several numerical solves of the underlying system of partial or ordinary differential equations. In this paper we present a new probabilistic approach to computing local sensitivities. The proposed method has several advantages over classical methods. Firstly, it operates within a constrained computational budget and provides a probabilistic quantification of uncertainty incurred in the sensitivities from this constraint. Secondly, information from previous sensitivity estimates can be recycled in subsequent computations, reducing the overall computational effort for iterative gradient-based calibration methods. The methodology presented is applied to two challenging test problems and compared against classical methods.
Cockayne, Jonathan
da87c8b2-fafb-4856-938d-50be8f0e4a5b
Duncan, Andrew B.
fcd49e5c-e1a6-4c8b-8e44-1d02c1b7fc48
Cockayne, Jonathan
da87c8b2-fafb-4856-938d-50be8f0e4a5b
Duncan, Andrew B.
fcd49e5c-e1a6-4c8b-8e44-1d02c1b7fc48
Cockayne, Jonathan and Duncan, Andrew B.
(2021)
Probabilistic gradients for fast calibration of differential equation models.
Pre-print.
(In Press)
Abstract
Calibration of large-scale differential equation models to observational or experimental data is a widespread challenge throughout applied sciences and engineering. A crucial bottleneck in state-of-the art calibration methods is the calculation of local sensitivities, i.e. derivatives of the loss function with respect to the estimated parameters, which often necessitates several numerical solves of the underlying system of partial or ordinary differential equations. In this paper we present a new probabilistic approach to computing local sensitivities. The proposed method has several advantages over classical methods. Firstly, it operates within a constrained computational budget and provides a probabilistic quantification of uncertainty incurred in the sensitivities from this constraint. Secondly, information from previous sensitivity estimates can be recycled in subsequent computations, reducing the overall computational effort for iterative gradient-based calibration methods. The methodology presented is applied to two challenging test problems and compared against classical methods.
Text
Probabilistic Gradients for Fast Calibration of Differential Equation Models
- Author's Original
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Submitted date: 2 September 2020
Accepted/In Press date: 22 February 2021
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Local EPrints ID: 451785
URI: http://eprints.soton.ac.uk/id/eprint/451785
PURE UUID: c5a577c5-534c-47a7-a76a-648d94a99464
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Date deposited: 27 Oct 2021 16:32
Last modified: 17 Mar 2024 04:09
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Author:
Andrew B. Duncan
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