Stability of public transportation systems in case of random failures and intended attacks - a case study from Switzerland

This paper presents the first results of a study analyzing railway network stability and the spreading dynamics of disastrous events with the potential to cause system-wide blockades using an interdisciplinary graph theoretical assessment. It introduces the modelling of railway transport that is ass...

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Bibliographic Details
Published in4th IET International Conference on System Safety 2009. Incorporating the SaRS Annual Conference p. 1B3
Main Authors Dorbritz, R, Weidmann, U
Format Conference Proceeding
LanguageEnglish
Published Stevenage IET 2009
Subjects
Combinatorial mathematics
Maintenance and reliability
Railway industry
Systems theory applications in industry
Systems theory applications in transportation
scale free network
railway accidents
interdisciplinary graph theoretical assessment
disastrous events spreading dynamics
graph theory
disasters
Swiss railway network
subnetwork infrastructure
complex networks
intended attack
failure analysis
public transportation system
railways
power law regime
railway network stability
random failure
railway transport
random error
stability
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Summary:This paper presents the first results of a study analyzing railway network stability and the spreading dynamics of disastrous events with the potential to cause system-wide blockades using an interdisciplinary graph theoretical assessment. It introduces the modelling of railway transport that is assumed to consist of five sub-network levels including infrastructure and energy. For the sub-network infrastructure, first results of the effects of random errors and intended node deletions are presented for four different test areas including the Swiss railway network (standard gauge). It is shown the infrastructure sub-networks of the test areas are small-world networks with a node-degree distribution following a powerlaw regime, which means that they belong to the class of scale-free networks (SFN). SFNs are robust against random errors but vulnerable towards intended attacks. However, it will be shown that putting effort on the protection of only a few nodes can significantly reduce the spreading dynamics in both, spatial and temporal dimension. (6 pages)
ISBN:1849191956
9781849191951
DOI:10.1049/cp.2009.1538