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Cyber-Physical Systems Virtual Organization
Read-only archive of site from September 29, 2023.
CPS-VO
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Projects
CPS: Synergy: Collaborative Research: Managing Uncertainty in the Design of Safety-Critical Aviation Systems
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Submitted by Samuel Guyer on Thu, 08/27/2015 - 1:29pm
Project Details
Lead PI:
Jason Rife
Co-PI(s):
Samuel Guyer
Performance Period:
10/01/13
-
09/30/16
Institution(s):
Tufts University
Sponsor(s):
National Science Foundation
Award Number:
1329341
2970 Reads. Placed 39 out of 804 NSF CPS Projects based on total reads on all related artifacts.
Abstract:
The objective of this project is to research tools to manage uncertainty in the design and certification process of safety-critical aviation systems. The research focuses on three innovative ideas to support this objective. First, probabilistic techniques will be introduced to specify system-level requirements and bound the performance of dynamical components. These will reduce the design costs associated with complex aviation systems consisting of tightly integrated components produced by many independent engineering organizations. Second, a framework will be created for developing software components that use probabilistic execution to model and manage the risk of software failure. These techniques will make software more robust, lower the cost of validating code changes, and allow software quality to be integrated smoothly into overall system-level analysis. Third, techniques from Extreme Value Theory will be applied to develop adaptive verification and validation procedures. This will enable early introduction of new and advanced aviation systems. These systems will initially have restricted capabilities, but these restrictions will be gradually relaxed as justified by continual logging of data from in-service products. The three main research aims will lead to a significant reduction in the costs and time required for fielding new aviation systems. This will enable, for example, the safe and rapid implementation of next generation air traffic control systems that have the potential of tripling airspace capacity with no reduction in safety. The proposed methods are also applicable to other complex systems including smart power grids and automated highways. Integrated into the research is an education plan for developing a highly skilled workforce capable of designing safety critical systems. This plan centers around two main activities: (a) creation of undergraduate labs focusing on safety-critical systems, and (b) integration of safety-critical concepts into a national robotic snowplow competition. These activities will provide inspirational, real-world applications to motivate student learning.
Related Artifacts
Posters
CPS: Synergy: Collaborative Research: Managing Uncertainty in the Design of Safety-Critical Aviation Systems
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Publications
(Submitted) Improving Run-Time Bug Detection in CPS Software Using Program Slicing
Improving Run-Time Bug Detection in Aviation Software Using Program Slicing
Applying Machine Learning for Run-time Bug Detection in Aviation Software
Comparison of Fault-Tree Models for Fault Detection, Isolation, and Recovery Algorithms
Refining fault trees using aviation definitions for consequence severity
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CPS: Synergy: Collaborative Research: Managing Uncertainty in the Design of Safety-Critical Aviation Systems
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CPS Domains
Aerospace
Automotive
Certification
Smart Grid
Defense
Control
Energy
Robotics
Transportation
Validation and Verification
Foundations