Robotic exoskeletons are being increasingly and successfully used in neuro-rehabilitation therapy scenarios. Indeed, they allow patients to perform movements requiring more complex inter-joint coordination and gravity counterbalancing, including assisted object grasping. We propose a robust RGB-D camera-based approach for automated tracking of both still and moving objects that can be used for assisting the reaching/grasping tasks in the aforementioned scenarios. The proposed approach allows to work with non pre-processed objects, giving the possibility to propose a flexible therapy. Moreover, our system is specialized to estimate the pose of cylinder-like shaped objects to allow cylinder grasps with the help of a robotic hand orthosis.To validate our method both in terms of tracking and of reaching/ grasping performances, we present the results achieved conducting tests both on simulations and on real robotic-assisted tasks performed by a patient.
A robust real-time 3D tracking approach for assisted object grasping / Loconsole, Claudio; Stroppa, Fabio; Bevilacqua, Vitoantonio; Frisoli, Antonio. - STAMPA. - 8618:(2014), pp. 400-408. [10.1007/978-3-662-44193-0_50]
A robust real-time 3D tracking approach for assisted object grasping
Loconsole, Claudio;Bevilacqua, Vitoantonio;
2014-01-01
Abstract
Robotic exoskeletons are being increasingly and successfully used in neuro-rehabilitation therapy scenarios. Indeed, they allow patients to perform movements requiring more complex inter-joint coordination and gravity counterbalancing, including assisted object grasping. We propose a robust RGB-D camera-based approach for automated tracking of both still and moving objects that can be used for assisting the reaching/grasping tasks in the aforementioned scenarios. The proposed approach allows to work with non pre-processed objects, giving the possibility to propose a flexible therapy. Moreover, our system is specialized to estimate the pose of cylinder-like shaped objects to allow cylinder grasps with the help of a robotic hand orthosis.To validate our method both in terms of tracking and of reaching/ grasping performances, we present the results achieved conducting tests both on simulations and on real robotic-assisted tasks performed by a patient.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
