Systems that maintain state awareness and an accepted level of operational normalcy in response to disturbances, including threats of an unexpected and malicious nature.
Project
CPS: Frontiers: Collaborative Research: Foundations of Resilient CybEr-Physical Systems (FORCES)
This NSF Cyber-Physical Systems (CPS) Frontiers project "Foundations Of Resilient CybEr-physical Systems (FORCES)" focuses on the resilient design of large-scale networked CPS systems that directly interface with humans. FORCES aims to provide comprehensive tools that allow the CPS designers and operators to combine resilient control (RC) algorithms with economic incentive (EI) schemes.
Scientific Contributions
The project is developing RC tools to withstand a wide-range of attacks and faults; learning and control algorithms which integrate human actions with spatio-temporal and hybrid dynamics of networked CPS systems; and model-based design to assure semantically consistent representations across all branches of the project. Operations of networked CPS systems naturally depend on the systemic social institutions and the individual deployment choices of the humans who use and operate them. The presence of incomplete and asymmetric information among these actors leads to a gap between the individually and socially optimal equilibrium resiliency levels. The project is developing EI schemes to reduce this gap. The core contributions of the FORCES team, which includes experts in control systems, game theory, and mechanism design, are the foundations for the co-design of RC and EI schemes and technological tools for implementing them.
Expected Impacts
Resilient CPS infrastructure is a critical National Asset. FORCES is contributing to the development of new Science of CPS by being the first project that integrates networked control with game theoretic tools and the economic incentives of human decision makers for resilient CPS design and operation. The FORCES integrated co-design philosophy is being validated on two CPS domains: electric power distribution and consumption, and transportation networks. These design prototypes are being tested in real world scenarios. The team's research efforts are being complemented by educational offerings on resilient CPS targeted to a large and diverse audience.
Off
University of California at Berkeley
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National Science Foundation
Submitted by S. Sastry on December 18th, 2015
Project
CPS: Frontiers: Collaborative Research: Foundations of Resilient CybEr-Physical Systems (FORCES)
This CPS Frontiers project addresses highly dynamic Cyber-Physical Systems (CPSs), understood as systems where a computing delay of a few milliseconds or an incorrectly computed response to a disturbance can lead to catastrophic consequences. Such is the case of cars losing traction when cornering at high speed, unmanned air vehicles performing critical maneuvers such as landing, or disaster and rescue response bipedal robots rushing through the rubble to collect information or save human lives. The preceding examples currently share a common element: the design of their control software is made possible by extensive experience, laborious testing and fine tuning of parameters, and yet, the resulting closed-loop system has no formal guarantees of meeting specifications.
The vision of the project is to provide a methodology that allows for complex and dynamic CPSs to meet real-world requirements in an efficient and robust way through the formal synthesis of control software. The research is developing a formal framework for correct-by-construction control software synthesis for highly dynamic CPSs with broad applications to automotive safety systems, prostheses, exoskeletons, aerospace systems, manufacturing, and legged robotics.
The design methodology developed here will improve the competitiveness of segments of industry that require a tight integration between hardware and highly advanced control software such as: automotive (dynamic stability and control), aerospace (UAVs), medical (prosthetics, orthotics, and exoskeleton design) and robotics (legged locomotion). To enhance the impact of these efforts, the PIs are developing interdisciplinary teaching materials to be made freely available and disseminating their work to a broad audience.
Off
Massachusetts Institute of Technology
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National Science Foundation
Asuman Ozdaglar
Submitted by Saurabh Amin on December 18th, 2015
Project
CPS: Frontiers: Collaborative Research: Foundations of Resilient CybEr-Physical Systems (FORCES)
This NSF Cyber-Physical Systems (CPS) Frontiers project "Foundations Of Resilient CybEr-physical Systems (FORCES)" focuses on the resilient design of large-scale networked CPS systems that directly interface with humans. FORCES aims to pr ovide comprehensive tools that allow the CPS designers and operators to combine resilient control (RC) algorithms with economic incentive (EI) schemes.
Scientific Contributions
The project is developing RC tools to withstand a wide-range of attacks and faults; learning and control algorithms which integrate human actions with spatio-temporal and hybrid dynamics of networked CPS systems; and model-based design to assure semantically consistent representations across all branches of the project. Operations of networked CPS systems naturally depend on the systemic social institutions and the individual deployment choices of the humans who use and operate them. The presence of incomplete and asymmetric information among these actors leads to a gap between the individually and socially optimal equilibrium resiliency levels. The project is developing EI schemes to reduce this gap. The core contributions of the FORCES team, which includes experts in control systems, game theory, and mechanism design, are the foundations for the co-design of RC and EI schemes and technological tools for implementing them.
Expected Impacts
Resilient CPS infrastructure is a critical National Asset. FORCES is contributing to the development of new Science of CPS by being the first project that integrates networked control with game theoretic tools and the economic incentives of human decision makers for resilient CPS design and operation. The FORCES integrated co-design philosophy is being validated on two CPS domains: electric power distribution and consumption, and transportation networks. These design prototypes are being tested in real world scenarios. The team's research efforts are being complemented by educational offerings on resilient CPS targeted to a large and diverse audience.
Off
University of Michigan Ann Arbor
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National Science Foundation
Project
CPS: Frontiers: Collaborative Research: Foundations of Resilient CybEr-Physical Systems (FORCES)
This NSF Cyber-Physical Systems (CPS) Frontiers project "Foundations Of Resilient CybEr-physical Systems (FORCES)" focuses on the resilient design of large-scale networked CPS systems that directly interface with humans. FORCES aims to pr ovide comprehensive tools that allow the CPS designers and operators to combine resilient control (RC) algorithms with economic incentive (EI) schemes.
Scientific Contributions
The project is developing RC tools to withstand a wide-range of attacks and faults; learning and control algorithms which integrate human actions with spatio-temporal and hybrid dynamics of networked CPS systems; and model-based design to assure semantically consistent representations across all branches of the project. Operations of networked CPS systems naturally depend on the systemic social institutions and the individual deployment choices of the humans who use and operate them. The presence of incomplete and asymmetric information among these actors leads to a gap between the individually and socially optimal equilibrium resiliency levels. The project is developing EI schemes to reduce this gap. The core contributions of the FORCES team, which includes experts in control systems, game theory, and mechanism design, are the foundations for the co-design of RC and EI schemes and technological tools for implementing them.
Expected Impacts
Resilient CPS infrastructure is a critical National Asset. FORCES is contributing to the development of new Science of CPS by being the first project that integrates networked control with game theoretic tools and the economic incentives of human decision makers for resilient CPS design and operation. The FORCES integrated co-design philosophy is being validated on two CPS domains: electric power distribution and consumption, and transportation networks. These design prototypes are being tested in real world scenarios. The team's research efforts are being complemented by educational offerings on resilient CPS targeted to a large and diverse audience.
Off
Vanderbilt University
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National Science Foundaiton
Submitted by Xenofon Koutsoukos on December 18th, 2015
Event
IEEE UIC 2016
13th IEEE International Conference on Ubiquitous Intelligence and Computing (IEEE UIC 2016)
Ubiquitous sensors, devices, networks and information are paving the way towards a smart world in which computational intelligence is distributed throughout the physical environment to provide reliable and relevant services to people.
Event
GaM 2016
The 2nd International Workshop GRAPHS AS MODELS (GaM 2016)
a Satellite Event of ETAPS 2016,
Description
Event
ICAC 2016
13th IEEE International Conference on Autonomic Computing (ICAC 2016)
Wuerzburg, Germany, July 19-22, 2016 | http://icac2016.uni-wuerzburg.de/
In cooperation with USENIX and SPEC
CONFERENCE PATRONS
SAP, Huawei, Hewlett Packard Enterprise, Google, Microsoft
WORKSHOPS
Event
FORTE 2016
36th IFIP International Conference on Formal Techniques for Distributed Objects, Components and Systems (FORTE 2016)
Part of the DisCoTec 2016 event
FORTE 2016 is a forum for fundamental research on theory, models, tools, and applications for distributed systems. The conference solicits original contributions that advance the science and technologies for distributed systems, with special interest in the areas of:
Event
WRC2016
10th HiPEAC Workshop on Reconfigurable Computing (WRC'2016)
The HiPEAC Workshop on Reconfigurable Computing (WRC) provides a forum for researchers active in domains within the reconfigurable computing area. Its main focus is on reconfigurable architectures, tools and algorithms that facilitate reconfigurable systems and applications tailored for reconfigurable platforms.
Event
DAC 2016
Design Automation Conference 2016
Austin Convention Center, Austin, Texas | June 5 - 9, 2016 | www.dac.com