TY - GEN
T1 - Single-trial analysis of readiness potentials for lower limb exoskeleton control
AU - Jeong, Ji Hoon
AU - Lee, Min Ho
AU - Kwak, No Sang
AU - Lee, Seong Whan
PY - 2017/2/16
Y1 - 2017/2/16
N2 - Bran-machine interface (BMI) can be used for controlling of external devices such as the exoskeleton, robot arm, etc. For efficient communication between a user and machine, fast and accurate detection of user intention is important elements in the BMI application. For this reason, readiness potential (RP) is a useful feature that is possible to detect movement intention before the movement onset. To our knowledge, however, the analysis of single-Trial RP component has not been sufficiently investigated in the real-world application (e.g. powered exoskeleton or robot arm). In our study, we first validate a single-Trial RP performance in the lower limb exoskeleton environment where the user allows for voluntary walking. The experiments are executed in the two different walking conditions which are normal and exoskeleton walking. The Laplacian and common average reference (CAR) filters are applied to reduce spatial noise and regularized linear discriminant analysis (RLDA) is used as a classifier. Our results show the averaged classification accuracy of80.7% for 5 subjects. This study demonstrates a feasibility of RP-based BMI system for controlling of a lower limb exoskeleton.
AB - Bran-machine interface (BMI) can be used for controlling of external devices such as the exoskeleton, robot arm, etc. For efficient communication between a user and machine, fast and accurate detection of user intention is important elements in the BMI application. For this reason, readiness potential (RP) is a useful feature that is possible to detect movement intention before the movement onset. To our knowledge, however, the analysis of single-Trial RP component has not been sufficiently investigated in the real-world application (e.g. powered exoskeleton or robot arm). In our study, we first validate a single-Trial RP performance in the lower limb exoskeleton environment where the user allows for voluntary walking. The experiments are executed in the two different walking conditions which are normal and exoskeleton walking. The Laplacian and common average reference (CAR) filters are applied to reduce spatial noise and regularized linear discriminant analysis (RLDA) is used as a classifier. Our results show the averaged classification accuracy of80.7% for 5 subjects. This study demonstrates a feasibility of RP-based BMI system for controlling of a lower limb exoskeleton.
KW - Brain-machine interface
KW - Lower limb exoskeleton
KW - Readiness potential
KW - Single-Trial analysis
UR - http://www.scopus.com/inward/record.url?scp=85016032557&partnerID=8YFLogxK
U2 - 10.1109/IWW-BCI.2017.7858156
DO - 10.1109/IWW-BCI.2017.7858156
M3 - Conference contribution
AN - SCOPUS:85016032557
T3 - 5th International Winter Conference on Brain-Computer Interface, BCI 2017
SP - 50
EP - 52
BT - 5th International Winter Conference on Brain-Computer Interface, BCI 2017
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 5th International Winter Conference on Brain-Computer Interface, BCI 2017
Y2 - 9 January 2017 through 11 January 2017
ER -