Mechanical Design, Modelling and Control of a Novel Aerial Manipulator
This addresses the problem of precise aerial manipulation for robotics applications, but it appears incremental as it builds on existing control and design methods.
The paper tackled the design and control of a new aerial manipulator by optimizing its mechanical structure and thruster geometry based on desired end-effector forces, and developed kinematic/dynamic models with an adaptive backstepping controller to precisely position the end-effector, achieving performance demonstrated through simulation of a manipulation task.
In this paper a novel aerial manipulation system is proposed. The mechanical structure of the system, the number of thrusters and their geometry will be derived from technical optimization problems. The aforementioned problems are defined by taking into consideration the desired actuation forces and torques applied to the end-effector of the system. The framework of the proposed system is designed in a CAD Package in order to evaluate the system parameter values. Following this, the kinematic and dynamic models are developed and an adaptive backstepping controller is designed aiming to control the exact position and orientation of the end-effector in the Cartesian space. Finally, the performance of the system is demonstrated through a simulation study, where a manipulation task scenario is investigated.