Markov chain model for delay distribution in train schedules: Assessing the effectiveness of time allowances

Abstract Train movements are subject to disturbances and disruptions, which may cause late departures and/or late arrivals at particular locations (e.g., terminals, stations, crossings) with respect to their pre-determined times. To prevent possible deviations from the scheduled times, time allowances are added to the process times (i.e., running times) as time supplements and to the time interval between successive trains (i.e., minimum headway) as buffer times. The amount of time allowances is decided during the timetable planning process and their contribution to the service quality is monitored in actual operation. The adequacy of time allowances results in punctual train operations, which is one of the primary interests of service users and providers. Because the sequence of train departure and arrival times can be viewed as a stochastic process, the performance of train operations may be analyzed and modeled using Markov chains. We modeled train departure and arrival delays at stations as states and analyzed the successive state changes along train paths in a single track railway. This allowed us to predict train states at certain event time steps and to estimate steady-state delay probabilities. The former may be used to reschedule train movements and the latter to measure timetable robustness.

[1]  Pavle Kecman,et al.  Predictive modelling of running and dwell times in railway traffic , 2015, Public Transp..

[2]  Thorsten Büker,et al.  Stochastic modelling of delay propagation in large networks , 2012, J. Rail Transp. Plan. Manag..

[3]  Lucas P. Veelenturf,et al.  An overview of recovery models and algorithms for real-time railway rescheduling , 2014 .

[4]  James J. Solberg Modeling Random Processes for Engineers and Managers , 2008 .

[5]  Johanna Törnquist Krasemann,et al.  Quantifying railway timetable robustness in critical points , 2013, J. Rail Transp. Plan. Manag..

[6]  Iunio Iervolino,et al.  Stochastic modeling of recovery from seismic shocks , 2015 .

[7]  Bernd Heidergott,et al.  A coupling approach to estimating the Lyapunov exponent of stochastic max-plus linear systems , 2011, Eur. J. Oper. Res..

[8]  Dennis Huisman,et al.  Optimisation Models for Railway Timetabling , 2014 .

[9]  Francesco Corman,et al.  A Review of Online Dynamic Models and Algorithms for Railway Traffic Management , 2015, IEEE Transactions on Intelligent Transportation Systems.

[10]  Richard J. Boucherie,et al.  A solvable queueing network model for railway networks and its validation and applications for the Netherlands , 2002, Eur. J. Oper. Res..

[11]  Pavle Kecman,et al.  Online Data-Driven Adaptive Prediction of Train Event Times , 2015, IEEE Transactions on Intelligent Transportation Systems.

[12]  Ingo A. Hansen,et al.  Online train delay recognition and running time prediction , 2010, 13th International IEEE Conference on Intelligent Transportation Systems.

[13]  Francesco Corman,et al.  Train delay evolution as a stochastic process , 2015 .

[14]  I A Hansen INCREASE OF CAPACITY THROUGH OPTIMIZED TIMETABLING , 2004 .

[15]  Jan van der Wal,et al.  An Application of the Semi Markovian Decision Approach for Train Conflict Resolution on a Vital Dutch Railway Section , 2009 .

[16]  Ingo A. Hansen,et al.  Performance indicators for railway timetables , 2013, 2013 IEEE International Conference on Intelligent Rail Transportation Proceedings.

[17]  Matthias Müller-Hannemann,et al.  Stochastic Delay Prediction in Large Train Networks , 2011, ATMOS.