Abstract
With the rapid development of railway traffic, traffic safety has become a focus. The ZPW-2000A jointless track circuit is an important part of train control systems. Currently, the fault detection of the ZPW-2000A jointless track circuit still relies on the experience of maintenance personnel, which can introduce several problems, such as a low fault detection efficiency and large amounts of required labor. Although some artificial intelligence fault detection algorithms for the ZPW-2000A track circuit have been developed, their detection accuracy is not high enough to meet the needs of large-scale applications, and due to security requirements, the actual ZPW-2000A track circuit fault data cannot be directly obtained in large quantities. To solve these problems, an equivalent theoretical model of the Chinese ZPW-2000A jointless track circuit is proposed by using four-terminal network theory. Through this equivalent theoretical model, the original fault data were collected. Considering that the relationship between fault data and fault types of the ZPW-2000A jointless track circuit is not obvious, a deep belief network was designed to detect the fault modes of the ZPW-2000A jointless track circuit. In order to optimize the deep belief network performance, the particle swarm optimization algorithm optimized by the genetic algorithm (GAPSO) was selected to optimize the deep belief network. The simulation experiments indicated that the optimized deep belief network could achieve a 98.5% fault detection accuracy and a 98.6% F1 Score rate, which showed that the deep belief network optimization by the particle swarm optimization algorithm which was optimized by the genetic algorithm (GAPSO-DBN) model proposed in this paper, had high accuracy and robustness. The results show that it had higher accuracy and robustness than other fault detection methods, and it can greatly improve the level of ZPW-2000A track circuit fault detection in the future.
Highlights
In recent years, high-speed railways have developed rapidly and become a popular means of transportation for travel
The deep belief network optimization by the particle swarm optimization algorithm which was optimized by the genetic algorithm (GAPSO-DBN) was applied to the fault detection of the ZPW-2000A jointless track circuit, and highly accurate and robust fault detection was achieved
The reason that the GAPSO-DBN model is suitable for ZPW-2000A jointless track circuit fault detection is that the DBN is an excellent deep structure space optimization algorithm, which is more suitable for solving the problem of fault detection in which the relationship between original data and classification results is not obvious
Summary
High-speed railways have developed rapidly and become a popular means of transportation for travel. Z. Zheng et al.: Research on Fault Detection for ZPW-2000A Jointless Track Circuit Based on Deep Belief Network. The ZPW-2000A jointless track circuit is mainly composed of a transmitter, transmission cable equipment (including matching transformer, service parallel thermoplastic (SPT) transmission cable, and cable analog network), a 29-m tuning area, a rail, and compensation capacitance and receiving equipment. Z. Zheng et al.: Research on Fault Detection for ZPW-2000A Jointless Track Circuit Based on Deep Belief Network TABLE 2. Different transmission networks can be connected based on the actual system structure, and a theoretical model of the ZPW-2000A jointless track circuit can be established. The corresponding relationship between the input voltage U5 and current I5 and the output voltage U4 and current I4 in the tuning area of the transmitter is as follows: U5 I5
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
