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S.K. Abburu, C. Casanueva, C.J. O'Reilly, "Network Theory Approach to Analysing Knock-On Effects in Rail Vehicle Design", in J. Pombo, (Editor), "Proceedings of the Sixth International Conference on Railway Technology: Research, Development and Maintenance", Civil-Comp Press, Edinburgh, UK, Online volume: CCC 7, Paper 14.4, 2024, doi:10.4203/ccc.7.14.4

Keywords: knock-on effects, early-stage design, rail vehicle design, network theory, subsystem interaction, traction system.

Abstract

Rail vehicle models have become increasingly complex, posing challenges in extracting insights using traditional model representations as they require numerous iterations to achieve a satisfactory solution. This complexity leads to high computational and time costs and possibly resulting in inefficient vehicle design. To alleviate these limitations, network models are proposed as an alternative representation in this paper. These models enable the analysis of structure, behaviour, and patterns of interactions, facilitating an understanding of knock-on effects across disciplines and subsystems. The terminology, benefits, and capabilities of network theory in early-stage vehicle design are presented in this paper, along with the aspects to consider and methods for developing network models. The applicability of network theory metrics and algorithms is demonstrated using a railway traction system example. Results indicate that the proposed representations can capture complex system knock-on effects across disciplines and subsystems.

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Front Page Browse CCC CCP CSETS CTR IJRT Other Authors Search Purchase Guide FAQ Contact us	Civil-Comp Conferences ISSN 2753-3239 CCC: 7 PROCEEDINGS OF THE SIXTH INTERNATIONAL CONFERENCE ON RAILWAY TECHNOLOGY: RESEARCH, DEVELOPMENT AND MAINTENANCE Edited by: J. Pombo Paper 14.4 Network Theory Approach to Analysing Knock-On Effects in Rail Vehicle Design S.K. Abburu, C. Casanueva and C.J. O'Reilly The Centre for ECO2 Vehicle Design, KTH Royal Institute of Technology, Stockholm, Sweden doi:10.4203/ccc.7.14.4 Full Bibliographic Reference for this paper S.K. Abburu, C. Casanueva, C.J. O'Reilly, "Network Theory Approach to Analysing Knock-On Effects in Rail Vehicle Design", in J. Pombo, (Editor), "Proceedings of the Sixth International Conference on Railway Technology: Research, Development and Maintenance", Civil-Comp Press, Edinburgh, UK, Online volume: CCC 7, Paper 14.4, 2024, doi:10.4203/ccc.7.14.4 Keywords: knock-on effects, early-stage design, rail vehicle design, network theory, subsystem interaction, traction system. Abstract Rail vehicle models have become increasingly complex, posing challenges in extracting insights using traditional model representations as they require numerous iterations to achieve a satisfactory solution. This complexity leads to high computational and time costs and possibly resulting in inefficient vehicle design. To alleviate these limitations, network models are proposed as an alternative representation in this paper. These models enable the analysis of structure, behaviour, and patterns of interactions, facilitating an understanding of knock-on effects across disciplines and subsystems. The terminology, benefits, and capabilities of network theory in early-stage vehicle design are presented in this paper, along with the aspects to consider and methods for developing network models. The applicability of network theory metrics and algorithms is demonstrated using a railway traction system example. Results indicate that the proposed representations can capture complex system knock-on effects across disciplines and subsystems. download the full-text of this paper (PDF, 1537 Kb) go to the previous paper go to the next paper return to the table of contents return to the volume description
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