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Towards the development of an operational digital twin

Towards the development of an operational digital twin
Towards the development of an operational digital twin
A digital twin is a powerful new concept in computational modelling that aims to produce a one-to-one mapping of a physical structure, operating in a specific context, into the digital domain. The development of a digital twin provides clear benefits in improved predictive performance and in aiding robust decision making for operators and asset managers. One key feature of a digital twin is the ability to improve the predictive performance over time, via improvements of the digital twin. An important secondary function is the ability to inform the user when predictive performance will be poor. If regions of poor performance are identified, the digital twin must offer a course of action for improving its predictive capabilities. In this paper three sources of improvement are investigated; (i) better estimates of the model parameters, (ii) adding/updating a data-based component to model unknown physics, and (iii) the addition of more physics-based modelling into the digital twin. These three courses of actions (along with taking no further action) are investigated through a probabilistic modelling approach, where the confidence of the current digital twin is used to inform when an action is required. In addition to addressing how a digital twin targets improvement in predictive performance, this paper also considers the implications of utilising a digital twin in a control context, particularly when the digital twin identifies poor performance of the underlying modelling assumptions. The framework is applied to a three-storey shear structure, where the objective is to construct a digital twin that predicts the acceleration response at each of the three floors given an unknown (and hence, unmodelled) structural state, caused by a contact nonlinearity between the upper two floors. This is intended to represent a realistic challenge for a digital twin, the case where the physical twin will degrade with age and the digital twin will have to make predictions in the presence of unforeseen physics at the time of the original model development phase.
2571-631X
235-265
Gardner, Paul
9a8c2fa5-fe94-4254-975e-09a981467d61
Dal Borgo, Mattia
7eeac32d-7dc9-4645-89cc-acee5a293867
Ruffini, Valentina
5305d274-c50b-4ed2-ad81-c8c8e1a6b524
Hughes, Aidan J.
b847c1e7-762e-4a1d-b40c-9cdbf75a8cd0
Zhu, Yichen
da8872f6-b6f7-4537-8353-fa4a1738dff2
Wagg, David J.
7aa7d661-df7e-4ecc-86b1-823d4adaf05f
Gardner, Paul
9a8c2fa5-fe94-4254-975e-09a981467d61
Dal Borgo, Mattia
7eeac32d-7dc9-4645-89cc-acee5a293867
Ruffini, Valentina
5305d274-c50b-4ed2-ad81-c8c8e1a6b524
Hughes, Aidan J.
b847c1e7-762e-4a1d-b40c-9cdbf75a8cd0
Zhu, Yichen
da8872f6-b6f7-4537-8353-fa4a1738dff2
Wagg, David J.
7aa7d661-df7e-4ecc-86b1-823d4adaf05f

Gardner, Paul, Dal Borgo, Mattia, Ruffini, Valentina, Hughes, Aidan J., Zhu, Yichen and Wagg, David J. (2020) Towards the development of an operational digital twin. Vibration, 3 (3), 235-265. (doi:10.3390/vibration3030018).

Record type: Article

Abstract

A digital twin is a powerful new concept in computational modelling that aims to produce a one-to-one mapping of a physical structure, operating in a specific context, into the digital domain. The development of a digital twin provides clear benefits in improved predictive performance and in aiding robust decision making for operators and asset managers. One key feature of a digital twin is the ability to improve the predictive performance over time, via improvements of the digital twin. An important secondary function is the ability to inform the user when predictive performance will be poor. If regions of poor performance are identified, the digital twin must offer a course of action for improving its predictive capabilities. In this paper three sources of improvement are investigated; (i) better estimates of the model parameters, (ii) adding/updating a data-based component to model unknown physics, and (iii) the addition of more physics-based modelling into the digital twin. These three courses of actions (along with taking no further action) are investigated through a probabilistic modelling approach, where the confidence of the current digital twin is used to inform when an action is required. In addition to addressing how a digital twin targets improvement in predictive performance, this paper also considers the implications of utilising a digital twin in a control context, particularly when the digital twin identifies poor performance of the underlying modelling assumptions. The framework is applied to a three-storey shear structure, where the objective is to construct a digital twin that predicts the acceleration response at each of the three floors given an unknown (and hence, unmodelled) structural state, caused by a contact nonlinearity between the upper two floors. This is intended to represent a realistic challenge for a digital twin, the case where the physical twin will degrade with age and the digital twin will have to make predictions in the presence of unforeseen physics at the time of the original model development phase.

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Accepted/In Press date: 2 September 2020
e-pub ahead of print date: 4 September 2020
Published date: September 2020

Identifiers

Local EPrints ID: 443658
URI: http://eprints.soton.ac.uk/id/eprint/443658
ISSN: 2571-631X
PURE UUID: a94dc79d-5c98-4011-a94e-732766887bf5
ORCID for Mattia Dal Borgo: ORCID iD orcid.org/0000-0003-4263-0513

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Date deposited: 07 Sep 2020 16:31
Last modified: 16 Mar 2024 09:15

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Contributors

Author: Paul Gardner
Author: Mattia Dal Borgo ORCID iD
Author: Valentina Ruffini
Author: Aidan J. Hughes
Author: Yichen Zhu
Author: David J. Wagg

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