TY - GEN
T1 - Use of multi-agent system to switch driving strategy in rail transit and procedure simulation
AU - Guo, Y. D.
AU - Zhang, C.
AU - Lu, S. F.
N1 - Publisher Copyright:
© 2020 Taylor & Francis Group, London.
PY - 2020
Y1 - 2020
N2 - The present paper proposes a multi-agent control system for rail transit. The multi-agent system (MAS) consists of multiple train agents, station agents and a central agent. The implementation of the proposed system is based on distributed optimal control. In the proposed system, each train agent can directly obtain information from the neighboring train agents. Each train agent consists of five subsystems, which are train data set, safety inspection system, timetable inspection system, energy optimization system and trajectory generate system. The train agent can optimize the speed trajectory according to the running state of adjacent trains with the cooperation of the five subsystems. The built-in algorithm of the proposed system can infer the driving strategy (such as time-priority or distance-priority) that should be adopted based on specific situations, which provides a good anti-disturbance ability. Furthermore, the distributed optimization method enables the system to perform a multi-objective optimization in a short time when the system is disturbed.
AB - The present paper proposes a multi-agent control system for rail transit. The multi-agent system (MAS) consists of multiple train agents, station agents and a central agent. The implementation of the proposed system is based on distributed optimal control. In the proposed system, each train agent can directly obtain information from the neighboring train agents. Each train agent consists of five subsystems, which are train data set, safety inspection system, timetable inspection system, energy optimization system and trajectory generate system. The train agent can optimize the speed trajectory according to the running state of adjacent trains with the cooperation of the five subsystems. The built-in algorithm of the proposed system can infer the driving strategy (such as time-priority or distance-priority) that should be adopted based on specific situations, which provides a good anti-disturbance ability. Furthermore, the distributed optimization method enables the system to perform a multi-objective optimization in a short time when the system is disturbed.
UR - http://www.scopus.com/inward/record.url?scp=85108919985&partnerID=8YFLogxK
U2 - 10.1201/9781003000716-25
DO - 10.1201/9781003000716-25
M3 - Conference Proceeding
AN - SCOPUS:85108919985
SN - 9780367430191
T3 - Sustainable Buildings and Structures: Building a Sustainable Tomorrow - Proceedings of the 2nd International Conference in Sustainable Buildings and Structures, ICSBS 2019
SP - 192
EP - 198
BT - Sustainable Buildings and Structures
A2 - Papadikis, Konstantinos
A2 - Chin, Chee S.
A2 - Galobardes, Isaac
A2 - Gong, Guobin
A2 - Guo, Fangyu
PB - CRC Press/Balkema
T2 - 2nd International Conference in Sustainable Buildings and Structures, ICSBS 2019
Y2 - 25 October 2019 through 27 October 2019
ER -