A data-driven agent-based model of congestion and scaling dynamics of rapid transit systems
Authored by Erika Fille Legara, Christopher Monterola, Othman Nasri Bin, Vicknesh Selvam
Date Published: 2015
DOI: 10.1016/j.jocs.2015.03.006
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Abstract
Investigating congestion in train rapid transit systems (RTS) in today's
urban cities is a challenge compounded by limited data availability and
difficulties in model validation. Here, we integrate information from
travel smart card data, a mathematical model of route choice, and a
full-scale agent-based model of the Singapore RTS to provide a more
comprehensive understanding of the congestion dynamics than can be
obtained through analytical modelling alone. Our model is empirically
validated, and allows for close inspection of congestion and scaling
dynamics. By adjusting our model, we can estimate the effective capacity
of the RTS trains as well as replicate the penultimate station effect, where commuters travel backwards to the preceding station to catch a
seat, sacrificing time for comfort. Using current data, the crowdedness
in all 121 stations appears to be distributed log-normally. We find that
increasing the current population (2 million) beyond a factor of
approximately 10\% leads to an exponential deterioration in service
quality. We also show that incentivizing commuters to avoid the most
congested hours can bring modest improvements to the service quality.
Finally, our model can be used to generate simulated data for
statistical analysis when such data are not empirically available, as is
often the case. (C) 2015 Elsevier B.V. All rights reserved.
Tags
Network
Smart-card data