Abstract
Cable-stayed bridges are damaged by multiple factors such as natural disasters, weather, and vehicle load. In particular, if the stayed cable, which is an essential and weak component of the cable-stayed bridge, is damaged, it may adversely affect the adjacent cables and worsen the bridge structure condition. Therefore, we must accurately determine the condition of the cable with a technology-based evaluation strategy. In this paper, we propose a deep learning model that allows us to locate the damaged cable and estimate its cross-sectional area. To obtain the data required for the deep learning training, we use the tension data of the reduced area cable, which are simulated in the Practical Advanced Analysis Program (PAAP), a robust structural analysis program. We represent the sensor data of the damaged cable-stayed bridge as a graph composed of vertices and edges using tension and spatial information of the sensors. We apply the sensor geometry by mapping the tension data to the graph vertices and the connection relationship between sensors to the graph edges. We employ a Graph Neural Network (GNN) to use the graph representation of the sensor data directly. GNN, which has been actively studied recently, can treat graph-structured data with the most advanced performance. We train the GNN framework, the Message Passing Neural Network (MPNN), to perform two tasks to identify damaged cables and estimate the cable areas. We adopt a multi-task learning method for more efficient optimization. We show that the proposed technique achieves high performance with the cable-stayed bridge data generated from PAAP.
Highlights
Cable-stayed bridges, one of the essential transportation infrastructures in modern society, are damaged and corroded by external environments such as natural disasters, climate, ambient vibrations, and vehicle loads
We propose a Graph Neural Network (GNN) to evaluate the cable cross-sectional area reduction caused by corrosion or fracture of structures
We proposed a damage assessment method of a cable-stayed bridge applying the graph representation on Message Passing Neural Network (MPNN)
Summary
Cable-stayed bridges, one of the essential transportation infrastructures in modern society, are damaged and corroded by external environments such as natural disasters, climate, ambient vibrations, and vehicle loads. The condition of the structure deteriorates, and the bridge loses its function. When the cable starts to be damaged, the stiffness and cross-sectional area decrease [2]. We cannot directly know the damaged cable and its crosssectional area only with raw data collected from the sensors on the bridge, such as the cable tension. Structural health conditions of cable-stayed bridges are generally monitored based on cable tension changes related to cable area parameters. A machine learning model is one of the damage detection techniques that identify damage location and degree. We present a fundamental understanding of the cable-stayed bridge model and our proposed approach for damage detection. Advanced Analysis Program (PAAP), is introduced, followed by our cable-stayed bridge model. We introduce a deep learning theory to understand Message Passing Neural
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
