Tesi etd-01242024-111443 |
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Tipo di tesi
Tesi di laurea magistrale
Autore
LUPI, MARCO
URN
etd-01242024-111443
Titolo
Design and Usability Analysis for a Humanoid Robot Interface for a Robotic Avatar
Dipartimento
INGEGNERIA DELL'INFORMAZIONE
Corso di studi
INGEGNERIA ROBOTICA E DELL'AUTOMAZIONE
Relatori
relatore Prof. Bicchi, Antonio
correlatore Prof. Grioli, Giorgio
correlatore Prof. Grioli, Giorgio
Parole chiave
- Alter-Ego
- EMG signals
- humanoid robot interface
- Myo Gesture Control Armband
- qb-move
- stiffness
- SUS test
- teleoperation
- usability
Data inizio appello
20/02/2024
Consultabilità
Tesi non consultabile
Riassunto
Thesis in collaboration with Lorenzo Incerpi.
This work presents the teleoperation control of a manipulator, in which the operator uses his own muscle activity to directly regulate the rigidity. In the first phase, for position control, we synthesized a gravity compensation control for a 6-Dof manipulator built with variable stiffness actuators (VSA). Instead, for rigidity control, the operator wears a Myo Armband bracelet, a wearable device which records electromyographic impulses from the operator's arm skin. We carried out an experimental campaign, including a variety of participants with varying technological and educational backgrounds, in order to comprehend the system's performance and usefulness. Alter-Ego X, a semi-anthropomorphic robot with soft hands and VSA qb-move, was employed for this investigation. Following a brief training phase, each subject completed three tasks using three distinct configurations: variable stiffness that the operator could regulate, maximum stiffness, and minimum stiffness. Using the System Usability Scale (SUS) questionnaire, we do system usability research. It is clear from the test results that one that directly affects the manipulator's rigidity with his own muscle activity is the best method, as well as from the answers to the SUS questionnaires that were given to the operators following the experiments.
This work presents the teleoperation control of a manipulator, in which the operator uses his own muscle activity to directly regulate the rigidity. In the first phase, for position control, we synthesized a gravity compensation control for a 6-Dof manipulator built with variable stiffness actuators (VSA). Instead, for rigidity control, the operator wears a Myo Armband bracelet, a wearable device which records electromyographic impulses from the operator's arm skin. We carried out an experimental campaign, including a variety of participants with varying technological and educational backgrounds, in order to comprehend the system's performance and usefulness. Alter-Ego X, a semi-anthropomorphic robot with soft hands and VSA qb-move, was employed for this investigation. Following a brief training phase, each subject completed three tasks using three distinct configurations: variable stiffness that the operator could regulate, maximum stiffness, and minimum stiffness. Using the System Usability Scale (SUS) questionnaire, we do system usability research. It is clear from the test results that one that directly affects the manipulator's rigidity with his own muscle activity is the best method, as well as from the answers to the SUS questionnaires that were given to the operators following the experiments.
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Tesi non consultabile. |