A Machine-Learning-Based Approach for Railway Track Monitoring Using Acceleration Measured on an In-Service Train

Malekjafarian, Abdollah; Sarrabezolles, Chalres-Antoine; Khan, Muhammad Arslan; Golpayegani, Fatemeh

doi:10.3390/s23177568

Cited by 9 publications

(12 citation statements)

References 59 publications

(99 reference statements)

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“…Most of the existing research focused on railway clouds is devoted to specific cloudbased railways applications [37]. These applications cover automatic train supervision [38], virtual coupling [39], track surveillance and monitoring [40,41], fault detection in railway infrastructure components [42], predictive maintenance [43], smart ticketing systems [44,45], train movements prediction [46], operation and maintenance of rail power supply systems [47], and security-related issues [48,49].…”

Section: Related Workmentioning

confidence: 99%

Railway Cloud: Management and Orchestration Functionality Designed as Microservices

Atanasov,

Pencheva,

Trifonov

et al. 2024

Applied Sciences

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The cloudification and virtualisation of railway functions have the potential to improve railway operation efficiency, reliability, safety, and security, as well as to enhance passenger experience by offering innovative services. This paper considers issues related to the management and orchestration of railway clouds that host cloudified railway functions. A microservices-based approach to the design of railway cloud management and orchestration functionality is proposed. The basic railway cloud concepts were defined, and functionality related to the basic orchestration of the railway cloud and deployments is analysed in order to derive the requirements of platform resources and workload management. This functionality is further designed in the form of microservices, meaning that they could possibly be used in orchestration applications to enable improvements in scalability, fault isolation, and data security. The design of microservices follows the principles of the Representational State of Transfer (REST) application programming interface (API) as a set of interlinked resources. Resources related to railway cloud orchestration are identified with their associated data, relationships to other resources, and applicable methods. The resources’ methods are used in railway applications to implement the required orchestration functionality and to maintain the state of railway cloud orchestration processes. To verify the synthesised microservices, the common orchestration application logic and microservices’ logic were modelled, and it was proved that the orchestration processes, which run concurrently, expose equivalent behaviour. The proposed approach was validated using a simulation, aiming to evaluate injected latency as a key performance indicator for the reliability and safety of railway operations. Additionally, some safety and security issues related to railway cloud management and orchestration are considered.

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Section: Related Workmentioning

confidence: 99%

Railway Cloud: Management and Orchestration Functionality Designed as Microservices

Atanasov,

Pencheva,

Trifonov

et al. 2024

Applied Sciences

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“…The collected data is significantly constrained by specific installation positions, posing difficulties in supporting a comprehensive analysis of tracks in the area of interest for decision-makers. A current trend in railway health monitoring to overcome this limitation is to install accelerometers on trains (Chudzikiewicz et al, 2014;Fernández-Bobadilla and Martin, 2023;Malekjafarian et al, 2023) utilized accelerometers on wheelsets to compute a defined track quality indicator, while (Malekjafarian et al, 2021) successfully differentiated between healthy and damaged tracks using accelerometers in the bogie on a service train. They assumed that accelerometers installed on wheelsets or in the bogie were the most important, considering the purpose of the track quality indicator (close to the track), the existing installation, and their lesser susceptibility to the suspension system.…”

Section: Introductionmentioning

confidence: 99%

Identification of optimal accelerometer placement on trains for railway switch wear monitoring via multibody simulation

Hu,

Lau,

Dai

et al. 2024

Front. Built Environ.

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Accelerometers play a crucial role in the railway industry, especially in track monitoring. Traditionally, they are placed on the railway tracks or often on bridges to monitor the health and condition of the infrastructure. Recently, there has been an increased focus on using regular trains to monitor the condition of railway infrastructure. Often, the sensors are placed based on certain assumptions without much scientific evidence or support. This paper utilizes the multibody simulation software GENSYS to identify the optimal placement of accelerometers on a passenger train for monitoring railway switch wear. Switch wear profiles were generated systematically and used as input for the simulations, studying acceleration at a total of 93 locations distributed among the wheelsets, bogies, and carbody. Based on both time and frequency domain analyses, optimal sensor locations were identified, generally close to the first bogie or wheelset at the leading carbody. Accelerations generated by the wheelset passing the switch can also be captured in the carbody, but it is important to note that these are several orders lower in magnitude compared to the acceleration on the wheelset. If accelerometers are to be placed in the carbody, correct sensitivity must be chosen, and a high-pass filter should be applied to capture the acceleration signals associated with switch wear. The study confirms that there is a direct correlation between the depth of switch wear and the magnitude of the acceleration. It remains effective even under various curve radii and train speeds.

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“…Aloisio et al [18] built classification models based on multinomial logistic regression (MLR) and artificial neural networks (ANNs); they calibrated seismic data that were theoretically less affected by personal bias. Malekjafarian et al [19] proposed an artificial neural network (ANN) algorithm to deal with the acceleration response energy of trains, using the acceleration response measured on trains in service to detect the stiffness loss of track sublayers.…”

Section: Introductionmentioning

confidence: 99%

Identification of Key Factors Influencing Sound Insulation Performance of High-Speed Train Composite Floor Based on Machine Learning

Wang,

Yao,

Zhang

et al. 2023

Acoustics

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The body of a high-speed train is a composite structure composed of different materials and structures. This makes the design of a noise-reduction scheme for a car body very complex. Therefore, it is important to clarify the key factors influencing sound insulation in the composite structure of a car body. This study uses machine learning to evaluate the key factors influencing the sound insulation performance of the composite floor of a high-speed train. First, a comprehensive feature database is constructed using sound insulation test results from a large number of samples obtained from laboratory acoustic measurements. Subsequently, a machine learning model for predicting the sound insulation of a composite floor is developed based on the random forest method. The model is used to analyze the sound insulation contributions of different materials and structures to the composite floor. Finally, the key factors influencing the sound insulation performance of composite floors are identified. The results indicate that, when all material characteristics are considered, the sound insulation and surface density of the aluminum profiles and the sound insulation of the interior panels are the three most important factors affecting the sound insulation of the composite floor. Their contributions are 8.5%, 7.3%, and 6.9%, respectively. If only the influence of the core material is considered, the sound insulation contribution of layer 1 exceeds 15% in most frequency bands, particularly at 250 and 500 Hz. The damping slurry contributed to 20% of the total sound insulation above 1000 Hz. The results of this study can provide a reference for the acoustic design of composite structures.

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A Machine-Learning-Based Approach for Railway Track Monitoring Using Acceleration Measured on an In-Service Train

Cited by 9 publications

References 59 publications

Railway Cloud: Management and Orchestration Functionality Designed as Microservices

Railway Cloud: Management and Orchestration Functionality Designed as Microservices

Identification of optimal accelerometer placement on trains for railway switch wear monitoring via multibody simulation

Identification of Key Factors Influencing Sound Insulation Performance of High-Speed Train Composite Floor Based on Machine Learning

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