Tesi etd-09122022-103543 |
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Tipo di tesi
Tesi di laurea magistrale
Autore
NEBBIA COLOMBA, RACHELE
URN
etd-09122022-103543
Titolo
Adaptive Admittance Control for Cooperative Manipulation using Dual Quaternion Representation and Logarithmic Mapping
Dipartimento
INGEGNERIA DELL'INFORMAZIONE
Corso di studi
INGEGNERIA ROBOTICA E DELL'AUTOMAZIONE
Relatori
relatore Prof. Bicchi, Antonio
tutor Dott. Figueredo, Luis
tutor Dott. Figueredo, Luis
Parole chiave
- Cooperative admittance controller
- Dual arm system
- Dual quaternions
Data inizio appello
29/09/2022
Consultabilità
Non consultabile
Data di rilascio
29/09/2092
Riassunto
This thesis addresses the problem of admittance control for bimanual and cooperative manipulators.
In this work we propose our cooperative adaptive admittance controller (CDAC), a novel solution that
integrates compliance behaviour defined within the dual quaternion logarithmic space—that accounts for the
coupled translation and rotation kinematics as well as for the cooperative variables defining the motion.
The overall scheme of the proposed framework consists of a stiffness adapter, cooperative admittance controller, and wrench adapter complete with an inner motion controller along with the cooperative system.
By describing the coupled motion exploiting the geometric features of dual quaternions, the desired compliant
behaviour is enforced on the whole dual-arm system and not on the single manipulator separately.
The proposed control, in addition with a stable stiffness adaptation policy within the cooperative task-space, is tested and validated by thorough simulation studies on two Franka Emika Panda robots carrying a shared object under varying loading conditions.
In this work we propose our cooperative adaptive admittance controller (CDAC), a novel solution that
integrates compliance behaviour defined within the dual quaternion logarithmic space—that accounts for the
coupled translation and rotation kinematics as well as for the cooperative variables defining the motion.
The overall scheme of the proposed framework consists of a stiffness adapter, cooperative admittance controller, and wrench adapter complete with an inner motion controller along with the cooperative system.
By describing the coupled motion exploiting the geometric features of dual quaternions, the desired compliant
behaviour is enforced on the whole dual-arm system and not on the single manipulator separately.
The proposed control, in addition with a stable stiffness adaptation policy within the cooperative task-space, is tested and validated by thorough simulation studies on two Franka Emika Panda robots carrying a shared object under varying loading conditions.
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