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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: Frontier: Collaborative Research: Compositional, Approximate, and Quantitative Reasoning for Medical Cyber-Physical Systems
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Submitted by Scott Smolka on Tue, 12/22/2015 - 12:08pm
Project Details
Lead PI:
Scott Smolka
Co-PI(s):
glimm
Radu Grosu
Performance Period:
05/01/15
-
04/30/20
Institution(s):
SUNY at Stony Brook
Sponsor(s):
National Science Foundation
Award Number:
1446832
1149 Reads. Placed 305 out of 804 NSF CPS Projects based on total reads on all related artifacts.
Abstract:
This project represents a cross-disciplinary collaborative research effort on developing rigorous, closed-loop approaches for designing, simulating, and verifying medical devices. The work will open fundamental new approaches for radically accelerating the pace of medical device innovation, especially in the sphere of cardiac-device design. Specific attention will be devoted to developing advanced formal methods-based approaches for analyzing controller designs for safety and effectiveness; and devising methods for expediting regulatory and other third-party reviews of device designs. The project team includes members with research backgrounds in computer science, electrical engineering, biophysics, and cardiology; the PIs will use a coordinated approach that balances theoretical, experimental and practical concerns to yield results that are intended to transform the practice of device design while also facilitating the translation of new cardiac therapies into practice. The proposed effort will lead to significant advances in the state of the art for system verification and cardiac therapies based on the use of formal methods and closed-loop control and verification. The animating vision for the work is to enable the development of a true in silico design methodology for medical devices that can be used to speed the development of new devices and to provide greater assurance that their behaviors match designers' intentions, and to pass regulatory muster more quickly so that they can be used on patients needing their care. The scientific work being proposed will serve this vision by providing mathematically robust techniques for analyzing and verifying the behavior of medical devices, for modeling and simulating heart dynamics, and for conducting closed-loop verification of proposed therapeutic approaches. The acceleration in medical device innovation achievable as a result of the proposed research will also have long-term and sustained societal benefits, as better diagnostic and therapeutic technologies enter into the practice of medicine more quickly. It will also yield a collection of tools and techniques that will be applicable in the design of other types of devices. Finally, it will contribute to the development of human resources and the further inclusion of under-represented groups via its extensive education and outreach programs, including intensive workshop experiences for undergraduates.
Related Artifacts
Presentations
Compositional, Approximate, and Quantitative Reasoning for Medical CPS
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Download
CyberCardia: Compositional, Approximate, and Quantitative Reasoning for Medical CPS
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Download
Posters
CyberCardia- Compositional, Approximate, and Quantitative Reasoning for Medical CPSs
|
Download
CPS Frontiers- Compositional, Approximate, and Quantitative Reasoning for Medical CPSs poster.pdf
|
Download
Publications
Lagrangian Reachabililty
In-silico pre-clinical trials for implantable cardioverter defibrillators
A novel {ICD} morphology discriminator to improve discrimination between Ventricular and Supraventricular tachycardias
Real-time Decision Policies with Predictable Performance
Three challenges in cyber-physical systems
Towards Model Checking of Implantable Cardioverter Defibrillators
Benchmark: Nonlinear Hybrid Automata Model of Excitable Cardiac Tissue
Computer Aided Clinical Trials for Implantable Cardiac Devices
High-Level Modeling for Computer-Aided Clinical Trials of Medical Devices
Automated Closed-Loop Model Checking of Implantable Pacemakers using Abstraction Trees
The Challenges of High-Confidence Medical Device Software
High-Confidence Medical Device Software Development
Estimability Analysis and Optimal Design in Dynamic Multi-scale Models of Cardiac Electrophysiology
{SMT-based Synthesis of Safe and Robust PID Controllers for Stochastic Hybrid Systems}
{Data-Driven Robust Control for Type 1 Diabetes Under Meal and Exercise Uncertainties}
Closed-loop quantitative verification of rate-adaptive pacemakers
Modeling bipolar stimulation of cardiac tissue
Mechanism for amplitude alternans in electrocardiograms and the initiation of spatiotemporal chaos
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CPS Domains
Control
Health Care
Simulation
Validation and Verification
Education
Foundations