From Ellipsoids to Midair Control of Dynamic Hitches
This work addresses the challenge of precise aerial manipulation for transportation tasks, representing an incremental advancement in dynamic modeling and control of cable interactions.
The paper tackles the problem of controlling dynamic hitches formed by interlacing cables with aerial vehicles, introducing an ellipsoid-based kinematic model and a quadratic programming-based controller that achieves stable, high-speed tracking of dynamic references in simulations.
The ability to manipulate and interlace cables using aerial vehicles can greatly improve aerial transportation tasks. Such interlacing cables create hitches by winding two or more cables around each other, which can enclose payloads or can further develop into knots. Dynamic modeling and control of such hitches are key to mastering inter-cable interactions in the context of cable-suspended aerial manipulation. This paper introduces an ellipsoid-based kinematic model to connect the geometric nature of a hitch created by two cables and the dynamics of the hitch driven by four aerial vehicles, which reveals the control-affine form of the system. As the constraint for maintaining tension of a cable is also control-affine, we design a quadratic programming-based controller that combines Control Lyapunov and High-Order Control Barrier Functions (CLF-HOCBF-QP) to precisely track a desired hitch position and system shape while enforcing safety constraints like cable tautness. We convert desired geometric reference configurations into target robot positions and introduce a composite error into the Lyapunov function to ensure a relative degree of one to the input. Numerical simulations validate our approach, demonstrating stable, high-speed tracking of dynamic references.