Adaptive Robust Control of Uncertain Euler-Lagrange Systems Using Gaussian Processes

This article proposes a novel adaptive robust control approach based on Gaussian processes (GPs) for the high-precision tracking problem of uncertain Euler-Lagrange (EL) systems with time-varying external disturbances. Given a prior dynamic model, the GP regression (GPR) technique is employed to obtain a nonparametric data-based uncertainty model, including its probabilistic confidence intervals. Based on the adaptive sliding mode control (ASMC) framework, the posterior means of GPs are utilized for dynamic compensation, whereas the posterior variances are applied to adjust the feedback gains. This proposed control strategy is robust against significant system uncertainty with low feedback gains. A novel adaptive law for updating hyperparameters based on tracking error feedback is presented, thereby improving the performance of both tracking control and GP modeling simultaneously. Compared to existing likelihood-based optimization methods, this hyperparameter adaptive law enables data-efficient and fast uncertainty learning for control applications. The proposed control strategy guarantees the semiglobal asymptotic convergence to zero tracking error with a specified probability. Simulations using an underwater robot model demonstrate that the utilization of GPs and hyperparameter adaptive law significantly improves the performance of tracking control and uncertainty learning.

Automated summary

This article proposes a novel adaptive robust control strategy based on Gaussian processes (GPs) for precise tracking of uncertain Euler-Lagrange (EL) systems with time-varying external disturbances. The strategy utilizes GP regression to obtain a nonparametric uncertainty model and employs adaptive sliding mode control to compensate dynamically using the posterior means of GPs and adjust feedback gains using posterior variances. An adaptive law for updating hyperparameters based on tracking error feedback is presented to improve both tracking control and GP modeling performance. Simulation results validate the effectiveness of the proposed strategy.