Physical and Data-Driven Models Hybridisation for Modelling the Dynamic State of a Four-Stroke Marine Diesel Engine

Book Chapter (2022)
Authors

Andrea Coraddu (TU Delft - Ship Design, Production and Operations)

Miltiadis Kalikatzarakis (University of Strathclyde)

Gerasimos Theotokatos (University of Strathclyde)

Rinze Geertsma (Netherlands Defence Academy, TU Delft - Ship Design, Production and Operations)

Luca Oneto (University of Genova)

Research Group
Ship Design, Production and Operations
Copyright
© 2022 A. Coraddu, Miltiadis Kalikatzarakis, Gerasimos Theotokatos, R.D. Geertsma, Luca Oneto
To reference this document use:
https://doi.org/10.1007/978-981-16-8618-4_6
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Publication Year
2022
Language
English
Copyright
© 2022 A. Coraddu, Miltiadis Kalikatzarakis, Gerasimos Theotokatos, R.D. Geertsma, Luca Oneto
Research Group
Ship Design, Production and Operations
Bibliographical Note
Green Open Access added to TU Delft Institutional Repository 'You share, we take care!' - Taverne project https://www.openaccess.nl/en/you-share-we-take-care Otherwise as indicated in the copyright section: the publisher is the copyright holder of this work and the author uses the Dutch legislation to make this work public.@en
Pages (from-to)
145-193
ISBN (print)
978-981-16-8617-7
ISBN (electronic)
978-981-16-8618-4
DOI:
https://doi.org/10.1007/978-981-16-8618-4_6
Reuse Rights

Other than for strictly personal use, it is not permitted to download, forward or distribute the text or part of it, without the consent of the author(s) and/or copyright holder(s), unless the work is under an open content license such as Creative Commons.

Abstract

Accurate, reliable, and computationally inexpensive models of the dynamic state of combustion engines are a fundamental tool to investigate new engine designs, develop optimal control strategies, and monitor their performance. The use of those models would allow to improve the engine cost-efficiency trade-off, operational robustness, and environmental impact. To address this challenge, two state-of-the-art alternatives in literature exist. The first one is to develop high fidelity physical models (e.g., mean value engine, zero-dimensional, and one-dimensional models) exploiting the physical principles that regulate engine behaviour. The second one is to exploit historical data produced by the modern engine control and automation systems or by high-fidelity simulators to feed data-driven models (e.g., shallow and deep machine learning models) able to learn an accurate digital twin of the system without any prior knowledge. The main issues of the former approach are its complexity and the high (in some case prohibitive) computational requirements. While the main issues of the latter approach are the unpredictability of their behaviour (guarantees can be proved only for their average behaviour) and the need for large amount of historical data. In this work, following a recent promising line of research, we describe a modelling framework that is able to hybridise physical and data driven models, delivering a solution able to take the best of the two approaches, resulting in accurate, reliable, and computationally inexpensive models. In particular, we will focus on modelling the dynamic state of a four-stroke diesel engine testing the performance (both in terms of accuracy, reliability, and computational requirements) of this solution against state-of-the-art physical modelling approaches on real-world operational data.

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