On the Stability of Undesirable Equilibria in the Quadratic Program Framework for Safety-Critical Control

Control Lyapunov functions (CLFs) and Control Barrier Functions (CBFs) have been used to develop provably safe controllers by means of quadratic programs (QPs). This framework guarantees safety in the form of trajectory invariance with respect to a given set, but it can introduce undesirable equilibrium points to the closed loop system, which can be asymptotically stable. In this work, we present a detailed study of the formation and stability of equilibrium points with the QP framework for a class of nonlinear systems. We introduce the useful concept of compatibility between a CLF and a family of CBFs, regarding the number of stable equilibrium points other than the CLF minimum. Using this concept, we derive a set of compatibility conditions on the parameters of a quadratic CLF and a family of quadratic CBFs that guarantee that all undesirable equilibrium points are not attractive. Furthermore, we propose an extension to the QP-based controller that dynamically modifies the CLF geometry in order to satisfy the compatibility conditions, guaranteeing safety and quasi-global convergence of the system state to the CLF minimum. Numeric simulations illustrate the applicability of the proposed method for safety-critical, deadlock-free robotic navigation tasks.