TY - JOUR
T1 - An Adaptive Mechatronic Exoskeleton for Force-Controlled Finger Rehabilitation
AU - Dickmann, Thomas
AU - Wilhelm, Nikolas J.
AU - Glowalla, Claudio
AU - Haddadin, Sami
AU - van der Smagt, Patrick
AU - Burgkart, Rainer
N1 - Publisher Copyright:
© Copyright © 2021 Dickmann, Wilhelm, Glowalla, Haddadin, van der Smagt and Burgkart.
PY - 2021/9/30
Y1 - 2021/9/30
N2 - This paper presents a novel mechatronic exoskeleton architecture for finger rehabilitation. The system consists of an underactuated kinematic structure that enables the exoskeleton to act as an adaptive finger stimulator. The exoskeleton has sensors for motion detection and control. The proposed architecture offers three main advantages. First, the exoskeleton enables accurate quantification of subject-specific finger dynamics. The configuration of the exoskeleton can be fully reconstructed using measurements from three angular position sensors placed on the kinematic structure. In addition, the actuation force acting on the exoskeleton is recorded. Thus, the range of motion (ROM) and the force and torque trajectories of each finger joint can be determined. Second, the adaptive kinematic structure allows the patient to perform various functional tasks. The force control of the exoskeleton acts like a safeguard and limits the maximum possible joint torques during finger movement. Last, the system is compact, lightweight and does not require extensive peripherals. Due to its safety features, it is easy to use in the home. Applicability was tested in three healthy subjects.
AB - This paper presents a novel mechatronic exoskeleton architecture for finger rehabilitation. The system consists of an underactuated kinematic structure that enables the exoskeleton to act as an adaptive finger stimulator. The exoskeleton has sensors for motion detection and control. The proposed architecture offers three main advantages. First, the exoskeleton enables accurate quantification of subject-specific finger dynamics. The configuration of the exoskeleton can be fully reconstructed using measurements from three angular position sensors placed on the kinematic structure. In addition, the actuation force acting on the exoskeleton is recorded. Thus, the range of motion (ROM) and the force and torque trajectories of each finger joint can be determined. Second, the adaptive kinematic structure allows the patient to perform various functional tasks. The force control of the exoskeleton acts like a safeguard and limits the maximum possible joint torques during finger movement. Last, the system is compact, lightweight and does not require extensive peripherals. Due to its safety features, it is easy to use in the home. Applicability was tested in three healthy subjects.
KW - adaptive control
KW - assisstive technologies
KW - exoskeletal analysis
KW - exoskeletal assist system
KW - interaction
KW - manipulator
KW - rehabilitate
UR - http://www.scopus.com/inward/record.url?scp=85117135361&partnerID=8YFLogxK
U2 - 10.3389/frobt.2021.716451
DO - 10.3389/frobt.2021.716451
M3 - Article
AN - SCOPUS:85117135361
SN - 2296-9144
VL - 8
JO - Frontiers Robotics AI
JF - Frontiers Robotics AI
M1 - 716451
ER -