TY - JOUR
T1 - Multiagent System-Based Near-Real-Time Trajectory and Microscopic Timetable Optimization for Rail Transit Network
AU - Guo, Yida
AU - Zhang, Cheng
AU - Wu, Chaoxian
AU - Lu, Shaofeng
N1 - Publisher Copyright:
© 2020 American Society of Civil Engineers.
PY - 2021/2/1
Y1 - 2021/2/1
N2 - In the rail transit field, the practical operation process suffers from potential energy waste caused by disturbances. The present paper proposes a multiagent system (MAS) to reduce rail transit energy consumption when disturbances occur. The system is able to optimize speed trajectory and microscopic timetable for each train in near real time when disturbances occur. Two case studies have been carried out to investigate the feasibility and efficiency of the proposed methodology. In the first case study, three trains are simulated with 1,212 different scenarios with a disturbance that comes from the leading train. The results of those scenarios show that the proposed system is able to guarantee safety and has good potential in reducing energy consumption in such conditions. In the second case study, a train running among seven stations with potential delays is simulated. The result shows that each train agent can support a microscopic timetable optimization in near real time and results in a 13.40% energy savings. An additional 2,340 scenarios are simulated, and an average of 4.12% energy savings is achieved.
AB - In the rail transit field, the practical operation process suffers from potential energy waste caused by disturbances. The present paper proposes a multiagent system (MAS) to reduce rail transit energy consumption when disturbances occur. The system is able to optimize speed trajectory and microscopic timetable for each train in near real time when disturbances occur. Two case studies have been carried out to investigate the feasibility and efficiency of the proposed methodology. In the first case study, three trains are simulated with 1,212 different scenarios with a disturbance that comes from the leading train. The results of those scenarios show that the proposed system is able to guarantee safety and has good potential in reducing energy consumption in such conditions. In the second case study, a train running among seven stations with potential delays is simulated. The result shows that each train agent can support a microscopic timetable optimization in near real time and results in a 13.40% energy savings. An additional 2,340 scenarios are simulated, and an average of 4.12% energy savings is achieved.
KW - Multiagent system (MAS)
KW - Near-real-time optimization
KW - Rail transit
KW - Timetable optimization
KW - Trajectory optimization
UR - http://www.scopus.com/inward/record.url?scp=85096531284&partnerID=8YFLogxK
U2 - 10.1061/JTEPBS.0000473
DO - 10.1061/JTEPBS.0000473
M3 - Article
AN - SCOPUS:85096531284
SN - 2473-2907
VL - 147
JO - Journal of Transportation Engineering Part A: Systems
JF - Journal of Transportation Engineering Part A: Systems
IS - 2
M1 - 04020153
ER -