TY - GEN
T1 - Topologic and dynamic resilience model of Chinese airport network
AU - Li, Bei Jie
AU - Du, Wen Bo
AU - Liu, Chen
AU - Cai, Kai Quan
PY - 2014
Y1 - 2014
N2 - The capability that transport networks stay robust against attacks or failures is of significant concern. In this paper, we proposed a model for resilience of Chinese airport network (CAN) with data from real world and obtain its performance in aspects of topology analysis and dynamic procedure. We compare changes in static properties, such as clustering coefficient, diameter and efficiency under various attack strategies together with random error and uncover that CAN is robust yet fragile. By examining cascading failure based on a local load redistribution rule, we further demonstrate that it would be relatively robust as long as the capacity of each airport is beyond a threshold, which is marked as the phase transition point. Adopting the initial load of a node i to be the throughput of that airport, we propose the critical value Tc, where capacity is the product of tolerance parameter T and its throughput. If viewing the initial load as kiα with ki being the degree of the node i , CAN would achieve the strongest robustness level in the case of α=1.1, distinct from that of BA network with scale-free property, whose best case happens when α=1.0. These results may be quite helpful to design and build a reliable air-traffic system.
AB - The capability that transport networks stay robust against attacks or failures is of significant concern. In this paper, we proposed a model for resilience of Chinese airport network (CAN) with data from real world and obtain its performance in aspects of topology analysis and dynamic procedure. We compare changes in static properties, such as clustering coefficient, diameter and efficiency under various attack strategies together with random error and uncover that CAN is robust yet fragile. By examining cascading failure based on a local load redistribution rule, we further demonstrate that it would be relatively robust as long as the capacity of each airport is beyond a threshold, which is marked as the phase transition point. Adopting the initial load of a node i to be the throughput of that airport, we propose the critical value Tc, where capacity is the product of tolerance parameter T and its throughput. If viewing the initial load as kiα with ki being the degree of the node i , CAN would achieve the strongest robustness level in the case of α=1.1, distinct from that of BA network with scale-free property, whose best case happens when α=1.0. These results may be quite helpful to design and build a reliable air-traffic system.
UR - https://www.scopus.com/pages/publications/84906542052
U2 - 10.1109/ICCA.2014.6871137
DO - 10.1109/ICCA.2014.6871137
M3 - 会议稿件
AN - SCOPUS:84906542052
SN - 9781479928378
T3 - IEEE International Conference on Control and Automation, ICCA
SP - 1460
EP - 1465
BT - 11th IEEE International Conference on Control and Automation, IEEE ICCA 2014
PB - IEEE Computer Society
T2 - 11th IEEE International Conference on Control and Automation, IEEE ICCA 2014
Y2 - 18 June 2014 through 20 June 2014
ER -