Shuttle Planning for Link Closures in Urban Public Transport Networks

Urban public transport systems must periodically close certain links for maintenance, which can have significant effects on the service provided to passengers. In practice, the effects of closures are mitigated by replacing the closed links with a simple shuttle service. However, alternative shuttle...

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Bibliographic Details
Published in:Transportation science 2016-08, Vol.50 (3), p.947-965
Main Authors: van der Hurk, Evelien, Koutsopoulos, Haris N., Wilson, Nigel, Kroon, Leo G., Maróti, Gábor
Format: Article
Language:English
Subjects:
Analysis
Budget constraint
Budgets
disruption management
line planning
Local transit
Operating costs
Passengers
public transport
Public transportation
Railway networks
shuttle planning
Traffic congestion
Transportation networks
Transportation systems
Urban areas
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Summary:Urban public transport systems must periodically close certain links for maintenance, which can have significant effects on the service provided to passengers. In practice, the effects of closures are mitigated by replacing the closed links with a simple shuttle service. However, alternative shuttle services could reduce inconvenience at a lower operating cost. This paper proposes a model to select shuttle lines and frequencies under budget constraints. We propose a new formulation that allows a minimal frequency restriction on any line that is operated and minimizes passenger inconvenience cost, which includes transfers and frequency-dependent waiting time costs. This model is applied to a shuttle design problem based on a real-world case study of the Massachusetts Bay Transportation Authority network of Boston, Massachusetts. The results show that additional shuttle routes can reduce passenger delay compared to the standard industry practice, while also distributing delay more equally over passengers, at the same operating budget. The results are robust under different assumptions about passenger route choice behavior. Computational experiments show that the proposed formulation, coupled with a preprocessing step, can be solved faster than prior formulations.
ISSN:0041-1655
1526-5447
DOI:10.1287/trsc.2015.0647