TY - GEN
T1 - A motion phase-based hybrid assistive controller for lower limb exoskeletons
AU - Baek, Eunyoung
AU - Song, Seok Ki
AU - Oh, Sehoon
AU - Mohammed, Samer
AU - Jeon, Doyoung
AU - Kong, Kyoungchul
PY - 2014
Y1 - 2014
N2 - Human motions are realized not only from voluntary contractions of muscles, but also by the sophisticated and variable impedance characteristics of the muscles. Such variable impedance characteristics are also required in assistive robotics, in particular wearable robots, in order to help humans in a natural and comfortable way. As the human muscles are controlled to exhibit a certain impedance characteristic in each motion phase, an assistive controller, i. e., the controller of an assistive robot, should also be able to realize different impedance characteristics. Moreover, the different impedance characteristics should be seamlessly switched for the sake of comfort, safety, and stability of a human interacting with an assistive robot. In this paper, a hybrid assistive controller that incorporates various assistive algorithms enabling the continuous and smooth change of impedance characteristics is proposed. The proposed algorithm has many degrees of freedom in the viewpoint of controller functionality. For the verification of the effectiveness of the proposed method in practice, it is applied to a lower limb exoskeleton actuated by compact rotary series elastic actuators.
AB - Human motions are realized not only from voluntary contractions of muscles, but also by the sophisticated and variable impedance characteristics of the muscles. Such variable impedance characteristics are also required in assistive robotics, in particular wearable robots, in order to help humans in a natural and comfortable way. As the human muscles are controlled to exhibit a certain impedance characteristic in each motion phase, an assistive controller, i. e., the controller of an assistive robot, should also be able to realize different impedance characteristics. Moreover, the different impedance characteristics should be seamlessly switched for the sake of comfort, safety, and stability of a human interacting with an assistive robot. In this paper, a hybrid assistive controller that incorporates various assistive algorithms enabling the continuous and smooth change of impedance characteristics is proposed. The proposed algorithm has many degrees of freedom in the viewpoint of controller functionality. For the verification of the effectiveness of the proposed method in practice, it is applied to a lower limb exoskeleton actuated by compact rotary series elastic actuators.
UR - http://www.scopus.com/inward/record.url?scp=84903148613&partnerID=8YFLogxK
U2 - 10.1109/AMC.2014.6823281
DO - 10.1109/AMC.2014.6823281
M3 - Conference contribution
AN - SCOPUS:84903148613
SN - 9781479923243
T3 - International Workshop on Advanced Motion Control, AMC
SP - 197
EP - 202
BT - 2014 IEEE 13th International Workshop on Advanced Motion Control, AMC 2014
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 2014 13th IEEE International Workshop on Advanced Motion Control, AMC 2014
Y2 - 14 March 2014 through 16 March 2014
ER -