Difference between revisions of "Projects"
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AI and Internet of Medical Things for Healthcare | AI and Internet of Medical Things for Healthcare | ||
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Real-Time Virtualization and Cloud Computing | Real-Time Virtualization and Cloud Computing | ||
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Dependable Industrial Internet of Things | Dependable Industrial Internet of Things | ||
Revision as of 09:20, 10 January 2020
The Cyber-Physical Systems Laboratory (CPSL) at Washington University in St. Louis performs cutting-edge research on real-time systems, wireless sensor networks, wireless health, and integrated systems that cross-cut these areas and other engineering disciplines.
Projects
AI and Internet of Medical Things for Healthcare
Real-Time Virtualization and Cloud Computing
Dependable Industrial Internet of Things
- Air Quality Network - Development of Cost-effective, Compact Electrical Ultrafine Particle (eUFP) Sizers and Wireless eUFP Sensor Network
- An Interdisciplinary Approach to Detecting Falls Among the Elderly
- CyberMech, a Novel Run-Time Substrate for Cyber-Mechanical Systems
- Submodular Optimization - Generalized Submodular Optimization for Integrated Networked Sensing Systems
- Home Area Networks for Smart Energy and Home Automation - Reliable Wireless Sensor Networking in Noisy Environments
- Protocols and Analysis for Predictable Wireless Sensor Networks
- Real-Time Scheduling for Parallel Tasks
- Real-Time Wireless Control Networks - Real-Time Scheduling and Analysis for Wireless Control Networks such as WirelessHART
- Reconfigurable MAC Architecture
- RT-Xen: Real-Time Virtualization based on Hierarchical Scheduling
- Structural Health Monitoring and Control - Cyber-Physical Co-Design of Wireless Monitoring and Control for Civil Infrastructure
- Internet of Medical Things
- WCPS: Wireless Cyber-Physical Simulator
- WSN Testbed - A Wireless Sensor Network Deployed in Computer Science Buildings.
Samples of Completed Projects
Real-Time Scheduling for Parallel Tasks [NSF XPS] Safety-Feature Modeling and Adaptive Resource Management for Mixed-Criticality Cyber-Physical Systems [NSF CPS]
Cyber-Physical Co-Design of Wireless Monitoring and Control for Civil Infrastructure [NSF CPS]
Development of Cost-effective, Compact Electrical Ultrafine Particle (eUFP) Sizers and Wireless eUFP Sensor Network [EPA]
CyberMech, a Novel Run-Time Substrate for Cyber-Mechanical Systems [NSF CPS]
Generalized Submodular Optimization for Integrated Networked Sensing Systems [NSF NeTS]
Protocols and Analysis for Predictable Wireless Sensor Networks [NSF NeTS]
Energy Consumption Profiling and Occupant Behavior Learning for Efficient Energy Use in Buildings [WU I-CARES]
Reliable Home Area Networking for Energy-Efficient Buildings and Homes [WU I-CARES]
Adaptive QoS Control in Distributed Real-Time Embedded Systems [NSF CAREER]
Home-Area Networks for Smart Energy and Home Automation [Broadcom, Emerson Climate Technologies]
Configurable Cyberphysical Instrument for Real-time Hybrid Testing [NSF MRI]
Wireless Sensor Networks Testbed [NSF CRI]
Unified and Configurable Power Management for Wireless Sensor Networks [NSF NeTS-NOSS]
- Adaptive Resource Control for Certifiable Systems
- Adaptive QoS Control in Distributed Real-Time Embedded Systems
- Agilla - A mobile agent middleware for wireless sensor networks.
- Agimone - A middleware system that combines multiple wireless sensor networks by allowing mobile agents to migrate between them.
- Configurable Cyberphysical Instrument for Real-time Hybrid Testing
- [Fluid Software Infrastructure for Wireless Sensor Networks] [NSF NeTS-NOSS]
- [Spatiotemporal Protocols and Analysis in Wireless Sensor Network] [NSF ITR]