Kernel-based Learning for Safe Control of Discrete-Time Unknown Systems under Incomplete Observations
Safe control for dynamical systems is critical, yet the presence of unknown dynamics poses significant challenges. In this paper, we present a learning-based control approach for tracking control of a class of high-order systems, operating under the constraint of partially observable states. The unc...
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Zusammenfassung: | Safe control for dynamical systems is critical, yet the presence of unknown
dynamics poses significant challenges. In this paper, we present a
learning-based control approach for tracking control of a class of high-order
systems, operating under the constraint of partially observable states. The
uncertainties inherent within the systems are modeled by kernel ridge
regression, leveraging the proposed strategic data acquisition approach with
limited state measurements. To achieve accurate trajectory tracking, a state
observer that seamlessly integrates with the control law is devised. The
analysis of the guaranteed control performance is conducted using Lyapunov
theory due to the deterministic prediction error bound of kernel ridge
regression, ensuring the adaptability of the approach in safety-critical
scenarios. To demonstrate the effectiveness of our proposed approach, numerical
simulations are performed, underscoring its contributions to the advancement of
control strategies. |
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DOI: | 10.48550/arxiv.2405.00822 |