Document Type
Paper
Abstract
Increasing access to space has driven demand for low cost, portable, and highly specialized robotic platforms to accurately simulate multi-dimensional space missions. Presented is an effective heterogeneous robotic system that emulates orbital motion from given control algorithms. This robotic platform is composed of a three degrees of freedom (3-DOF) holonomic omni wheel ground vehicle carrying a 6-DOF robotic manipulator, which results in a 9-DOF coupled moving manipulator system. The dynamical models are derived and feedback linearization is studied to control the system. The integrated controls and hardware result in an a sophisticated in-lab system that will be scalable from orbital motion to execution of complex tasks, including spaceflight rendezvous and proximity operations, servicing missions, and surface exploration and sampling.
Dynamics of a 9-DOF Heterogeneous Robotic Platform for Spacecraft Motion Emulation
Increasing access to space has driven demand for low cost, portable, and highly specialized robotic platforms to accurately simulate multi-dimensional space missions. Presented is an effective heterogeneous robotic system that emulates orbital motion from given control algorithms. This robotic platform is composed of a three degrees of freedom (3-DOF) holonomic omni wheel ground vehicle carrying a 6-DOF robotic manipulator, which results in a 9-DOF coupled moving manipulator system. The dynamical models are derived and feedback linearization is studied to control the system. The integrated controls and hardware result in an a sophisticated in-lab system that will be scalable from orbital motion to execution of complex tasks, including spaceflight rendezvous and proximity operations, servicing missions, and surface exploration and sampling.