TY - CONF
T1 - Predictive-Cognitive Maintenance for Advanced Integrated railway Management
AU - Arakistain, Ivan
AU - García, David
AU - Zamora, Diego
AU - Armijo, Alberto
AU - Fernandez-Navamuel, Ana
AU - Jimenez, Jose Carlos
AU - Beristain, Unai
N1 - Publisher Copyright:
© 2024 11th European Workshop on Structural Health Monitoring, EWSHM 2024. All rights reserved.
PY - 2024
Y1 - 2024
N2 - Railway systems play a vital role in modern transportation, and Predictive-Cognitive Maintenance (PCM) has emerged as a transformative approach in the context of Advanced Integrated Railway Management to ensure the safety, reliability, and efficiency of these systems. PCM leverages data analytics and machine learning to optimize railway system maintenance. This requires effective structural health monitoring (SHM) using low-cost sensor devices. This paper presents a prototype solar-powered wireless sensor node with a 3-axis MEMS accelerometer and energy-harvesting features for monitoring rail-track vibrations. The node contains a microcontroller that runs embedded machine learning models to preprocess the vibration data after train crossing. Abnormal vibrations indicative of defects were detected in real time using the TinyML inference at the edge. Instead of raw data, only the model results were wirelessly transmitted to a digital twin in the cloud. The digital twin aggregates data across the rail network for the system-level assessment of RUL and maintenance planning. This edge computing approach minimizes wireless transmission and cloud storage compared to raw sensor streaming. Embedded ML enables real-time damage detection, whereas cloud digital twins provide system-level prognostic insights. The solar-powered platform enables long-term remote monitoring at low cost without wiring or battery changes. A full-scale physical model was used to validate the edge node prototypes against calculation models and wired accelerometers for impulse loads. The results demonstrated that these nodes can provide a sensor layer for cost-effective PCM in railway systems. In summary, this study proposes an edge computing and embedded ML approach for SHM that integrates cloud-based digital twins to enable the predictive-cognitive maintenance of railway infrastructure. Wireless nodes demonstrate potential for low-cost, convenient, and automated rail health monitoring.
AB - Railway systems play a vital role in modern transportation, and Predictive-Cognitive Maintenance (PCM) has emerged as a transformative approach in the context of Advanced Integrated Railway Management to ensure the safety, reliability, and efficiency of these systems. PCM leverages data analytics and machine learning to optimize railway system maintenance. This requires effective structural health monitoring (SHM) using low-cost sensor devices. This paper presents a prototype solar-powered wireless sensor node with a 3-axis MEMS accelerometer and energy-harvesting features for monitoring rail-track vibrations. The node contains a microcontroller that runs embedded machine learning models to preprocess the vibration data after train crossing. Abnormal vibrations indicative of defects were detected in real time using the TinyML inference at the edge. Instead of raw data, only the model results were wirelessly transmitted to a digital twin in the cloud. The digital twin aggregates data across the rail network for the system-level assessment of RUL and maintenance planning. This edge computing approach minimizes wireless transmission and cloud storage compared to raw sensor streaming. Embedded ML enables real-time damage detection, whereas cloud digital twins provide system-level prognostic insights. The solar-powered platform enables long-term remote monitoring at low cost without wiring or battery changes. A full-scale physical model was used to validate the edge node prototypes against calculation models and wired accelerometers for impulse loads. The results demonstrated that these nodes can provide a sensor layer for cost-effective PCM in railway systems. In summary, this study proposes an edge computing and embedded ML approach for SHM that integrates cloud-based digital twins to enable the predictive-cognitive maintenance of railway infrastructure. Wireless nodes demonstrate potential for low-cost, convenient, and automated rail health monitoring.
KW - cognitive
KW - maintenance
KW - predictive
KW - Railway
KW - vibration anomaly
UR - http://www.scopus.com/inward/record.url?scp=85202547015&partnerID=8YFLogxK
U2 - 10.58286/29605
DO - 10.58286/29605
M3 - Paper
AN - SCOPUS:85202547015
T2 - 11th European Workshop on Structural Health Monitoring, EWSHM 2024
Y2 - 10 June 2024 through 13 June 2024
ER -