The space environment is very demanding and every mission requires careful assessment and preparation. This is especially true when operations are rather challenging as in the case of a multibody spacecraft and grasping mission. Therefore, the design and set-up of specific ground simulation techniques is mandatory in order to define and study the control law strategies to be later applied in orbit. The paper depicts the experimental activities carried out at the University of Rome 'La Sapienza' to experimentally simulate planar, controlled operations of orbiting manipulators. The architecture of the set-up, including the choice for limiting the friction, is discussed. Hardware selection and assembly issues, with reference to performance expected by simulation set-up, are detailed. Special attention is devoted to the kinematic state determination and trajectory reconstruction, to be obtained by sensors and devices located onboard the manipulators and validated by external means like webcams, which become a part of the simulation testbed itself. Relevant performance of each subsystem is described, and verified in robust closed loop grasping maneuvers. A second application of the same set-up, which is also helpful and currently used in formation flying studies, is introduced. © 2011 IEEE.
An experimental testbed to simulate space manipulators GNC / Monti, Riccardo; Barboni, Renato; Gasbarri, Paolo; Sabatini, Marco; Palmerini, Giovanni Battista. - STAMPA. - (2011), pp. 1-8. (Intervento presentato al convegno 2011 IEEE Aerospace Conference, AERO 2011 tenutosi a Big Sky, MT nel 5 March 2011 through 12 March 2011) [10.1109/aero.2011.5747480].
An experimental testbed to simulate space manipulators GNC
MONTI, RICCARDO;BARBONI, Renato;GASBARRI, Paolo;SABATINI, MARCO;PALMERINI, Giovanni Battista
2011
Abstract
The space environment is very demanding and every mission requires careful assessment and preparation. This is especially true when operations are rather challenging as in the case of a multibody spacecraft and grasping mission. Therefore, the design and set-up of specific ground simulation techniques is mandatory in order to define and study the control law strategies to be later applied in orbit. The paper depicts the experimental activities carried out at the University of Rome 'La Sapienza' to experimentally simulate planar, controlled operations of orbiting manipulators. The architecture of the set-up, including the choice for limiting the friction, is discussed. Hardware selection and assembly issues, with reference to performance expected by simulation set-up, are detailed. Special attention is devoted to the kinematic state determination and trajectory reconstruction, to be obtained by sensors and devices located onboard the manipulators and validated by external means like webcams, which become a part of the simulation testbed itself. Relevant performance of each subsystem is described, and verified in robust closed loop grasping maneuvers. A second application of the same set-up, which is also helpful and currently used in formation flying studies, is introduced. © 2011 IEEE.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
