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Issues of fitness for purpose in train simulation models: a review

Murray-Smith, D. J. (2022) Issues of fitness for purpose in train simulation models: a review. Simulation Notes Europe, 32(4), pp. 177-186. (doi: 10.11128/sne.32.on.10621)

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Abstract

Many simulation models representing the longitudinal dynamics of a train are based on a single point-mass description. This leads to a second-order nonlinear ordinary differential equation, together with algebraic relationships. More complex multi-mass models may be used for models representing long trains involving many separate vehicles. However, in both cases, accuracy is limited by important underlying assumptions, approximations and parametric uncertainties. Another important aspect of train models concerns the direction of information flow. Input variables within conventional train models may represent power or tractive force, with acceleration, speed and distance travelled as output variables. However, inverse simulation methods can also be used, with the required speed or distance as inputs and tractive force, power, or energy as outputs. This allows energy requirements to be established for a given schedule and is useful when investigating fuel or energy economy. Inverse methods can also be used in powertrain design, such as for hybrid hydrogen fuel-cell/battery-electric trains. Issues of fitness for purpose are important in all such applications, both in terms of model uncertainties and in the additional insight offered by inverse simulation methods.

Item Type:	Articles
Keywords:	Longitudinal train model, point mass, multi-mass, parametric uncertainties, inverse simulation, model testing, model quality.
Status:	Published
Refereed:	Yes
Glasgow Author(s) Enlighten ID:	Murray-Smith, Professor David
Authors:	Murray-Smith, D. J.
Subjects:	Q Science > QA Mathematics Q Science > QA Mathematics > QA76 Computer software T Technology > TF Railroad engineering and operation T Technology > TJ Mechanical engineering and machinery T Technology > TK Electrical engineering. Electronics Nuclear engineering
College/School:	College of Science and Engineering > School of Engineering
Journal Name:	Simulation Notes Europe
Journal Abbr.:	SNE
Publisher:	Arbeitsgemeinschaft Simulation
ISSN:	2305-9974
ISSN (Online):	2306-0271
Copyright Holders:	Copyright © 2023 EUROSIM / ARGESIM
First Published:	First published in Simulation Notes Europe 32(4): 177-186
Publisher Policy:	Reproduced in accordance with the publisher copyright policy

University Staff: Request a correction | Enlighten Editors: Update this record

References

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Deposit and Record Details

ID Code:	289304
Depositing User:	Professor David Murray-Smith
Datestamp:	11 Jan 2023 09:58
Last Modified:	12 Jan 2023 02:31
Date of acceptance:	8 November 2022
Date of first online publication:	December 2022
Date Deposited:	11 January 2023
Data Availability Statement:	No