Optimization of Coordinated Flow Control and Skip-stopping Schemes for
Urban Rail Stations Considering Platform Carrying Capacity
Abstract
The platform carrying capacity of urban rail transit stations is limited
and overcrowding of the platform will lead to serious safety risks for
passengers and trains. It is significant to collaborate on the
optimization of passenger flow strategy and skip-stopping scheme to
alleviate traffic pressure and ensure platform safety. This study
proposes and solves the joint optimization problem of coordinated flow
control and skip-stopping scheme considering platform carrying capacity.
Firstly, platform demand constraints and platform stranded constraints
are designed according to the maximum carrying capacity of the platform
to control the number of allowable arrivals ensuring platform safety.
Secondly, train arrival variable and train stop variable are introduced
to generate train skip-stopping index. Finally, considering the
characteristics of passengers' continuous arrival and platform carrying
capacity, a mixed integer programming model is established to minimize
the number of passengers outside the station and the number of
passengers stranded on the platform. Based on empirical data, this study
takes Beijing Batong line as a case study and uses the established model
to generate flow control strategy and skip-stopping schemes for each
station during morning rush hours. Experimental results show that
compared to the baseline without implementing the two proposed
strategies, the proposed collaborative optimization method can
effectively reduce the demand for staying at the platform and increase
the number of boarding passengers at downstream stations. Thus, the
balance between train capacity and passenger flow demand is maintained
while ensuring platform safety. Moreover, the proposed method can also
avoid overcrowding at downstream stations.