Abstract:
We present Barrier-based Simplex (Bb-Simplex), a new, provably correct design for runtime assurance of continuous and hybrid dynamical systems. Bb-Simplex is centered around the Simplex Control Architecture, which consists of a high-performance advanced controller that is not guaranteed to maintain safety of the plant, a verified-safe baseline controller, and a decision module that switches control of the plant between the two controllers to ensure safety without sacrificing performance.
In Bb-Simplex, barrier certificates are used to prove that the baseline controller ensures safety. Furthermore, Bb-Simplex features a new automated method for deriving, from the barrier certificate, the conditions for switching between the controllers. Our method is based on the Taylor expansion of the barrier certificate and yields computationally inexpensive switching conditions. We also propose extensions to Bb-Simplex to enable its use in hybrid systems, which have multiple modes each with its own dynamics, and to support its use when only approximate dynamics (not exact dynamics) are available, for both continuous-time and hybrid dynamical systems.
We consider a significant application of Bb-Simplex to microgrids featuring advanced controllers in the form of neural networks trained using reinforcement learning. The microgrids are modeled in RTDS, an industry-standard high-fidelity, real-time power systems simulator. Our results demonstrate that Bb-Simplex can automatically derive switching conditions for complex systems, the switching conditions are not overly conservative, and Bb-Simplex ensures safety even in the presence of adversarial attacks on the neural controller.
Dates
Tuesday, May 07, 2024 - 12:30pm to Tuesday, May 07, 2024 - 01:30pm
Location
NCS 120
Event Description
Event Title
Ph.D. Thesis Defense: 'A Barrier Certificate-based Simplex Architecture for Runtime Assurance for Continuous and Hybrid Systems', Amol Damare