Cyber-Physical Co-Design of Wireless Monitoring and Control for Civil Infrastructure
Abstract:
We are developing advanced distributed monitoring and control systems for civil infrastructure. The approach employs cyber-physical co-design of wireless sensor-actuator networks and structural monitoring and control algorithms. The unified cyber-physical system architecture provides reusable middleware services for developing hierarchical structural monitoring and control systems. The intellectual merit of this multi-disciplinary research includes (1) a unified middleware architecture and abstractions for hierarchical sensing and control; (2) a reusable middleware service library for hierarchical structural monitoring and control; (3) customizable time synchronization and synchronized sensing routines; (4) a holistic energy management scheme that maps structural monitoring and control onto a distributed wireless sensor-actuator architecture; (5) dynamic sensor and actuator activation strategies to optimize for the requirements of monitoring, computing, and control; and (6) deployment and empirical validation of structural health monitoring and control systems on representative lab structures and in-service multi-span bridges. While the system constitutes a case study, it will enable the development of general principles that would be applicable to a broad range of engineering cyber-physical systems. This research will result in a reduction in the lifecycle costs and risks related to our civil infrastructure. The multi-disciplinary team will disseminate results throughout the international research community through open-source software and sensor board hardware. Education and outreach activities will be held in conjunction with the Asia-Pacific Summer School in Smart Structures Technology jointly hosted by the US, Japan, China, and Korea.This poster will present an overview of the project and on-going research on (1) distributed, multi- level damage detection deployed on a full scale truss, (2) the Wireless Cyber-Physical Simulator (WCPS) for holistic wireless control system simulations combining realistic models for both physical systems and wireless networks, (3) case studies of wireless structural control systems of a large bridge and a building under the impacts of wireless communication delay and data loss,(4) a wireless sensor network monitoring a cable-stayed bridge in Korea, and (5) a modular, service-oriented software library for assembling structural health monitoring applications.
Submitted by Chenyang Lu
on
Abstract:
We are developing advanced distributed monitoring and control systems for civil infrastructure. The approach employs cyber-physical co-design of wireless sensor-actuator networks and structural monitoring and control algorithms. The unified cyber-physical system architecture provides reusable middleware services for developing hierarchical structural monitoring and control systems. The intellectual merit of this multi-disciplinary research includes (1) a unified middleware architecture and abstractions for hierarchical sensing and control; (2) a reusable middleware service library for hierarchical structural monitoring and control; (3) customizable time synchronization and synchronized sensing routines; (4) a holistic energy management scheme that maps structural monitoring and control onto a distributed wireless sensor-actuator architecture; (5) dynamic sensor and actuator activation strategies to optimize for the requirements of monitoring, computing, and control; and (6) deployment and empirical validation of structural health monitoring and control systems on representative lab structures and in-service multi-span bridges. While the system constitutes a case study, it will enable the development of general principles that would be applicable to a broad range of engineering cyber-physical systems. This research will result in a reduction in the lifecycle costs and risks related to our civil infrastructure. The multi-disciplinary team will disseminate results throughout the international research community through open-source software and sensor board hardware. Education and outreach activities will be held in conjunction with the Asia-Pacific Summer School in Smart Structures Technology jointly hosted by the US, Japan, China, and Korea.This poster will present an overview of the project and on-going research on (1) distributed, multi- level damage detection deployed on a full scale truss, (2) the Wireless Cyber-Physical Simulator (WCPS) for holistic wireless control system simulations combining realistic models for both physical systems and wireless networks, (3) case studies of wireless structural control systems of a large bridge and a building under the impacts of wireless communication delay and data loss,(4) a wireless sensor network monitoring a cable-stayed bridge in Korea, and (5) a modular, service-oriented software library for assembling structural health monitoring applications.