A bio-inspired algorithm for identification of critical components in the transportation networks

Zhang, X., Adamatzky, A., Yang, H., Mahadaven, S., Yang, X.-S., Wang, Q. and Deng, Y. (2014) A bio-inspired algorithm for identification of critical components in the transportation networks. Applied Mathematics and Computation, 248. pp. 18-27. ISSN 0096-3003 Available from: http://eprints.uwe.ac.uk/26992

Full text not available from this repository

Publisher's URL: http://dx.doi.org/10.1016/j.amc.2014.09.055


Critical components in a transportation or communication network are those which should be better protected or secured because their removal has a significant impact on the whole network. In such networks, they will be congested if they are being offered more traffic than it can process. In this paper, we employ principles of slime mould Physarum polycephalum foraging behaviour to identify the critical components in congested networks. When Physarum colonises a substrate, it develops a network of protoplasmic tube aimed at transporting nutrients and metabolites between distance parts of the cell. The protoplasmic network is continuously updating to minimize the transportation time, maximize the amount of cytoplasm pumped and minimize the overall length of the network. This optimization is achieved via a positive feedback between flux of cytoplasm and tube diameters. When a segment of a protoplasmic network is removed, the whole network reconfigures and thickness of tubes is updated till an equilibrium state is reached. The transient period from a disturbed state to an equilibrium state shows how critical the removed segment was. We develop a Physarum-inspired algorithm to identify critical links or nodes in a network by removing them from the network or calculating the transient period to new equilibrium state. The efficiency of the proposed method are demonstrated in numerical examples.

Item Type:Article
Uncontrolled Keywords:physarum, critical components, transportation system, optimization
Faculty/Department:Faculty of Environment and Technology > Department of Computer Science and Creative Technologies
ID Code:26992
Deposited By: Professor A. Adamatzky
Deposited On:25 Sep 2015 10:13
Last Modified:16 Dec 2016 07:58

Request a change to this item

Document Downloads

Total Document Downloads

More statistics for this item...