On-orbit servicing often requires the use of robotic arms, and a key asset in this kind of operations is autonomy. In this framework, the use of optical devices is a solution, already analyzed in many researches both for autonomous rendezvous and docking and for the evaluation of the control of the manipulator. In the present paper, simulations for assessing the controller performance are realized in a high-fidelity purposely developed software architecture, in which not only the selected 6 DOF space manipulator is modeled, but also a virtual camera, acquiring in the loop images of the target CAD model imported, is included in the GNC loop. This approach allows to emphasis several problems that would not emerge in simulations with ideal images. At the scope, a specific GNC architecture is developed, based on finite-state machine logic. According to this approach, two different IBVS strategies are alternatively performed, commanding only linear or angular velocity of the camera, switching between the two control techniques when the “stack” or “divergence” condition is triggered. In this way a stable and robust accomplishment of the tasks is achieved for many configurations and for different target models.
GNC architecture solutions for robust operations of a free-floating space manipulator via image based visual servoing / Marchionne, C.; Sabatini, M.; Gasbarri, P.. - (2019), pp. 1-15. (Intervento presentato al convegno 70th International astronautical congress, IAC 2019 tenutosi a Washington; United States).
GNC architecture solutions for robust operations of a free-floating space manipulator via image based visual servoing
Sabatini M.;Gasbarri P.
2019
Abstract
On-orbit servicing often requires the use of robotic arms, and a key asset in this kind of operations is autonomy. In this framework, the use of optical devices is a solution, already analyzed in many researches both for autonomous rendezvous and docking and for the evaluation of the control of the manipulator. In the present paper, simulations for assessing the controller performance are realized in a high-fidelity purposely developed software architecture, in which not only the selected 6 DOF space manipulator is modeled, but also a virtual camera, acquiring in the loop images of the target CAD model imported, is included in the GNC loop. This approach allows to emphasis several problems that would not emerge in simulations with ideal images. At the scope, a specific GNC architecture is developed, based on finite-state machine logic. According to this approach, two different IBVS strategies are alternatively performed, commanding only linear or angular velocity of the camera, switching between the two control techniques when the “stack” or “divergence” condition is triggered. In this way a stable and robust accomplishment of the tasks is achieved for many configurations and for different target models.| File | Dimensione | Formato | |
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