High-Order Matrix Control Barrier Functions: Well-Posedness and Feasibility via Matrix Relative Degree
It addresses a gap in safety-critical control for systems with matrix-valued constraints and high-order dynamics, which is relevant for robotics and autonomous systems.
This paper extends matrix control barrier functions to high-order dynamics, enabling enforcement of matrix-valued safety constraints (e.g., positive definiteness) for systems where control input does not appear in the first derivative. The framework ensures well-posedness and feasibility, demonstrated on a localization safety problem.
Control barrier functions (CBFs) provide an effective framework for enforcing safety in dynamical systems with scalar constraints. However, many safety constraints are more naturally expressed as matrix-valued conditions, such as positive definiteness or eigenvalue bounds - scalar formulations introduce potential nonsmoothness that complicates analysis. Matrix control barrier functions (MCBFs) address this limitation by directly enforcing matrix-valued safety constraints. Yet for constraints where the control input does not appear in the first derivative, high-order formulations are required. While such extensions are well understood in the scalar case, they remain largely unexplored in the matrix case. This paper develops high-order matrix control barrier functions (HOMCBFs) and establishes conditions ensuring well-posedness and feasibility of the associated constraints, enabling enforcement of matrix-valued safety constraints for systems with high-order dynamics. We further show that, using an optimal-decay HOMCBF formulation, forward invariance can be ensured while requiring control only over the minimum eigenspace. The framework is demonstrated on a localization safety problem by enforcing positive definiteness of the information matrix for a double integrator system with a nonlinear measurement model.