Application of Optimized BP Network in Bogie Condition Monitoring

The research and analysis of the technology of vehicle bogie condition monitoring combined with the basic principle of BP network is applied to the condition monitoring of vehicle bogies. The genetic algorithm is used to optimize the BP network, establish the optimal weight and threshold, and establish an ideal BP network model to complete the state monitoring. The dynamic model of the bogie is established by the knowledge of the dynamics of the rail vehicle, and the irregularity of the rail is used as an external stimulus to simulate the state of the vehicle running. Test analysis using an optimized BP network. It was found that the optimized BP network is more stable and accurate. With the continuous development of railway transportation, rail transit has occupied a very important position in the public transportation system. The safety and comfort of rail vehicles is an important factor affecting their development. The suspension system is a key component of the vehicle's travel department, and the performance of the suspension system directly affects the safety and comfort of the vehicle. The online real-time fault condition monitoring of the suspension system plays an important role in the safe and stable operation of the vehicle. Therefore, it is a hot research topic for domestic and foreign scholars to seek real-time and reliable suspension system fault diagnosis methods. At present, there are many fault diagnosis methods for rail vehicle suspension systems at home and abroad. There is a vehicle suspension system fault diagnosis based on IMM algorithm, vehicle suspension system fault diagnosis based on observation method, etc. The fault can only be alerted, and the fault cannot be further determined. Artificial neural network algorithm is a discipline developed on the basis of modern neurology. BP neural network is the most widely used. It adopts parallel distributed processing, learning and memory function, and nonlinear mapping ability, which can perform multi-fault identification, complex pattern recognition, etc., achieved good results in the fault diagnosis system. The combination of genetic algorithm and BP neural network algorithm realizes the recognition of corresponding faults from nonlinear and non-stationary signals. The walking part is an important part of the rail vehicle. It plays the role of carrying, pulling, running, and braking. It is a key link to determine the safety and dynamic performance of the train. This paper establishes a simulation model of orbital dynamics and performs data acquisition and processing. Genetic algorithm is used to optimize BP neural network algorithm for fault diagnosis of key components of vehicles.

Language

  • English

Media Info

  • Media Type: Web
  • Features: References;
  • Pagination: pp 157-165
  • Monograph Title: Resilience and Sustainable Transportation Systems

Subject/Index Terms

Filing Info

  • Accession Number: 01745260
  • Record Type: Publication
  • ISBN: 9780784482902
  • Files: TRIS, ASCE
  • Created Date: Jun 29 2020 3:02PM