Synthesis of Feedback Controller for Nonlinear Control Systems with Optimal Region of Attraction
This work addresses the challenge of ensuring stability in nonlinear control systems for applications in robotics and autonomous systems, representing an incremental improvement by integrating ROA optimization with existing control methods.
The authors tackled the problem of synthesizing feedback controllers for nonlinear dynamical systems to maximize the region of attraction (ROA), achieving this by co-optimizing ROA with traditional control objectives like LQR cost through stochastic optimization and deep neural network-based estimation.
We propose a framework for synthesizing a feedback control policy that maximizes the region of attraction (ROA) of a closed-loop nonlinear dynamical system. Our synthesis technique relies on stochastic optimization, which involves computation of an objective function capturing the ROA for a feedback control law. We employ a machine learning technique based on deep neural network to estimate the ROA for a given feedback controller. Overall, our technique is capable of synthesizing a controller co-optimizing traditional control objectives like LQR cost together with ROA. We demonstrate the efficacy of our technique through exhaustive experiments carried out on various nonlinear systems.