Use non-intrusive vibration sensors to capture and analyze the vibration patterns of structures. By employing an LSTM-autoencoder deep learning framework to accurately assess structural safety, evaluate building strength, calculate cable forces, and estimate scour levels at bridge piers. AI-driven predictions help identify trends in structural strength reduction, offering early warnings when critical thresholds are approached, enabling timely actions and informed decision-making.

The system integrates open meteorological data to assess changes in building strength before and after natural disasters. It provides detailed evaluations of structural safety in response to these events. Additionally, it converts geometric and material properties (such as those of cables or bridge piers) into actionable metrics, including cable force values and scour measurements.

With continuous monitoring via vibration sensing network modules, we provide reliable "Routine Health Check Reports" and "Real-Time Post-Disaster Inspection Reports." This ensures that maintenance units receive up-to-date safety information, particularly after natural disasters like earthquakes or typhoons.

The unified system interface consolidates real-time structural safety data and historical information for multiple buildings. Featuring a user-friendly, modular interface with graphical and categorical displays, the system leverages AI to track frequency trends and predict when safety thresholds will be reached. This allows for swift assessment of building conditions and facilitates the implementation of necessary protective measures.