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Abstract
The rapid increase of train speed has brought greater challenges to the safety and reliability of railway systems. Therefore, it is necessary to monitor the operation status of trains, infrastructure, and their operating environment in real time. Because the operation environment of railway systems is complex, the construction cost of wired monitoring systems is high, and it is difficult to achieve full coverage in the operation area of harsh environments, so wireless sensor networks are suitable for the status monitoring of railway systems. Energy resources of nodes are the basis of ensuring the lifecycle of wireless sensor networks, but severely restrict the sustainability of wireless sensor networks. A construction method of special wireless sensor networks for railway status monitoring, and an optimal energy resources allocation method of wireless sensor networks for intelligent railway systems are proposed in this paper. Through cluster head selection and rotating probability model, clustering generation and optimization model, and partial coverage model, the energy consumption of nodes can be minimized and balanced. The result of simulation experiment proved that the lifetime of wireless sensor networks can be maximized by the optimal energy resources allocation method based on clustering optimization and partial coverage model, based on polynomial time algorithm.
Highlights
Railway systems have become one of the main modes of transportation in the world
The special wireless sensor network for railway status monitoring is dedicated to real-time acquisition of service status information of railway infrastructure and its operating environment, and it can rapidly transmit monitoring data to remote data centers for the diagnosis and prediction of the service status of the system
We designed a double-layer communication network based on wireless sensor network for intelligent railway systems firstly
Summary
Railway systems have become one of the main modes of transportation in the world. The stability, reliability, and safety of railway systems are important. The service state monitoring of railway systems mainly relies on the combination of manual inspection, train inspection, and on-board inspection equipment. In order to improve the real-time and reliability of railway system service status monitoring, a cable-based status monitoring and transmission system can be constructed in critical monitoring areas. Fiber Bragg grating, and stress-strain monitoring and transmission technologies can be used to realize on-line monitoring of railway system infrastructure. Due to some drawbacks of cable-based communication itself, it is difficult for on-line monitoring systems based on wired communication to achieve full coverage of railway infrastructure
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