Time-Vertex Machine Learning for Optimal Sensor Placement in Temporal Graph Signals: Applications in Structural Health Monitoring
This work addresses the challenge of reducing deployment costs without compromising quality for structural health monitoring in infrastructure, representing an incremental improvement by combining existing techniques.
The paper tackled the problem of optimal sensor placement in structural health monitoring by proposing a Time-Vertex Machine Learning framework that integrates graph signal processing, time-domain analysis, and machine learning to minimize redundancy while preserving critical information, resulting in enhanced monitoring systems as demonstrated on bridge datasets for damage detection and signal reconstruction tasks.
Structural Health Monitoring (SHM) plays a crucial role in maintaining the safety and resilience of infrastructure. As sensor networks grow in scale and complexity, identifying the most informative sensors becomes essential to reduce deployment costs without compromising monitoring quality. While Graph Signal Processing (GSP) has shown promise by leveraging spatial correlations among sensor nodes, conventional approaches often overlook the temporal dynamics of structural behavior. To overcome this limitation, we propose Time-Vertex Machine Learning (TVML), a novel framework that integrates GSP, time-domain analysis, and machine learning to enable interpretable and efficient sensor placement by identifying representative nodes that minimize redundancy while preserving critical information. We evaluate the proposed approach on two bridge datasets for damage detection and time-varying graph signal reconstruction tasks. The results demonstrate the effectiveness of our approach in enhancing SHM systems by providing a robust, adaptive, and efficient solution for sensor placement.