Mixed μ-synthesis tracking control and disturbance rejection in a robotic digit of an impaired human hand for anthropomorphic coordination

In a partially impaired anthropomorphic hand, maintaining the movement coordination of the robotic digits with the central nervous system (CNS) and natural digits is crucial for robust performance. A challenge in the control perspective of movement coordination of a human hand is finding methods rob...

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Bibliographic Details
Published in:Biological cybernetics 2023-06, Vol.117 (3), p.221-247
Main Authors: Iqbal, Maryam, Imtiaz, Junaid, Mughal, Asif Mahmood
Format: Article
Language:English
Subjects:
Actuation
Angular position
Anthropomorphism
Bioinformatics
Biomechanics
Biomedical and Life Sciences
Biomedicine
Central nervous system
Complex Systems
Computer Appl. in Life Sciences
Controllers
Coordination
Disturbances
End effectors
Finger
Fingers
Hand
Human motion
Mechanical properties
Movement disorders
Mu-synthesis
Neurobiology
Neurosciences
Original Article
Rehabilitation
Robot arms
Robotics
Robust control
Time lag
Tracking control
Uncertainty
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Summary:In a partially impaired anthropomorphic hand, maintaining the movement coordination of the robotic digits with the central nervous system (CNS) and natural digits is crucial for robust performance. A challenge in the control perspective of movement coordination of a human hand is finding methods robust to the disturbances in a well-posed control problem of a biomechanical model. We use visco-elastic dynamics in the human palm frame of reference to explore the biomechanics of movement coordination to solve this control problem. Our biomechanical model incorporates the time delay due to actuation force, parametric uncertainty, exogenous disturbances, and sensory noise to constitute a 21-degree of freedom model. A mixed μ -synthesis controller, considering the real parametric uncertainty, represents the CNS in the control paradigm. We consider the robotic finger’s flexion movement when perturbed from the initial equilibrium. The controller provides feedback force at the joints to regulate the robotic finger movement. The index finger follows a reference trajectory of the joint angular position profile and stabilizes at a flexion angle of 1 rad/s at a time of 1 s. The main control objective is to keep the angular displacement of the finger joint constant when a disturbance force acts. We simulate the modeling scheme in MATLAB/ Simulink. The results demonstrate that our controller scheme is robust against the worst-case disturbance and achieves the desired performance value. Developing a biologically inspired neurophysiological controller with robust performance has many applications, including assistive rehabilitation devices, hand movement disorder diagnosis, and robotic manipulators.
ISSN:1432-0770
0340-1200
1432-0770
DOI:10.1007/s00422-023-00964-x