Learning Local Control Barrier Functions for Hybrid Systems
This addresses safety concerns for hybrid robotic systems, offering a more efficient and scalable solution compared to existing methods.
The paper tackles the problem of ensuring safety in hybrid robotic systems by proposing a learning-based approach to construct local Control Barrier Functions, resulting in a safe neural CBF-based switching controller that is computationally efficient and minimally invasive.
Hybrid dynamical systems are ubiquitous as practical robotic applications often involve both continuous states and discrete switchings. Safety is a primary concern for hybrid robotic systems. Existing safety-critical control approaches for hybrid systems are either computationally inefficient, detrimental to system performance, or limited to small-scale systems. To amend these drawbacks, in this paper, we propose a learning-enabled approach to construct local Control Barrier Functions (CBFs) to guarantee the safety of a wide class of nonlinear hybrid dynamical systems. The end result is a safe neural CBF-based switching controller. Our approach is computationally efficient, minimally invasive to any reference controller, and applicable to large-scale systems. We empirically evaluate our framework and demonstrate its efficacy and flexibility through two robotic examples including a high-dimensional autonomous racing case, against other CBF-based approaches and model predictive control.