Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot Study

Background: Realization of online control of an artificial or virtual arm using information decoded from EEG normally occurs by classifying different activation states or voluntary modulation of the sensorimotor activity linked to different overt actions of the subject. However, using a more natural...

Full description

Bibliographic Details
Main Authors: Attila Korik, Ronen Sosnik, Nazmul Siddique, Damien Coyle
Format: Article
Language:English
Published: Frontiers Media S.A. 2019-11-01
Series:Frontiers in Neurorobotics
Subjects:
Online Access:https://www.frontiersin.org/article/10.3389/fnbot.2019.00094/full
id doaj-fa61ae4859ca42bf82c72514f8a3d0e9
record_format Article
spelling doaj-fa61ae4859ca42bf82c72514f8a3d0e92020-11-25T02:03:01ZengFrontiers Media S.A.Frontiers in Neurorobotics1662-52182019-11-011310.3389/fnbot.2019.00094446033Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot StudyAttila Korik0Ronen Sosnik1Nazmul Siddique2Damien Coyle3Intelligent Systems Research Centre, Ulster University, Derry, United KingdomHybrid BCI Lab, Holon Institute of Technology, Holon, IsraelIntelligent Systems Research Centre, Ulster University, Derry, United KingdomIntelligent Systems Research Centre, Ulster University, Derry, United KingdomBackground: Realization of online control of an artificial or virtual arm using information decoded from EEG normally occurs by classifying different activation states or voluntary modulation of the sensorimotor activity linked to different overt actions of the subject. However, using a more natural control scheme, such as decoding the trajectory of imagined 3D arm movements to move a prosthetic, robotic, or virtual arm has been reported in a limited amount of studies, all using offline feed-forward control schemes.Objective: In this study, we report the first attempt to realize online control of two virtual arms generating movements toward three targets/arm in 3D space. The 3D trajectory of imagined arm movements was decoded from power spectral density of mu, low beta, high beta, and low gamma EEG oscillations using multiple linear regression. The analysis was performed on a dataset recorded from three subjects in seven sessions wherein each session comprised three experimental blocks: an offline calibration block and two online feedback blocks. Target classification accuracy using predicted trajectories of the virtual arms was computed and compared with results of a filter-bank common spatial patterns (FBCSP) based multi-class classification method involving mutual information (MI) selection and linear discriminant analysis (LDA) modules.Main Results: Target classification accuracy from predicted trajectory of imagined 3D arm movements in the offline runs for two subjects (mean 45%, std 5%) was significantly higher (p < 0.05) than chance level (33.3%). Nevertheless, the accuracy during real-time control of the virtual arms using the trajectory decoded directly from EEG was in the range of chance level (33.3%). However, the results of two subjects show that false-positive feedback may increase the accuracy in closed-loop. The FBCSP based multi-class classification method distinguished imagined movements of left and right arm with reasonable accuracy for two of the three subjects (mean 70%, std 5% compared to 50% chance level). However, classification of the imagined arm movement toward three targets was not successful with the FBCSP classifier as the achieved accuracy (mean 33%, std 5%) was similar to the chance level (33.3%). Sub-optimal components of the multi-session experimental paradigm were identified, and an improved paradigm proposed.https://www.frontiersin.org/article/10.3389/fnbot.2019.00094/fullbrain-computer interface (BCI)imagined 3D arm movementsonline motion trajectory predictionmultiple linear regression (mLR)filter-bank common spatial Patterns (FBCSP)electroencephalography
collection DOAJ
language English
format Article
sources DOAJ
author Attila Korik
Ronen Sosnik
Nazmul Siddique
Damien Coyle
spellingShingle Attila Korik
Ronen Sosnik
Nazmul Siddique
Damien Coyle
Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot Study
Frontiers in Neurorobotics
brain-computer interface (BCI)
imagined 3D arm movements
online motion trajectory prediction
multiple linear regression (mLR)
filter-bank common spatial Patterns (FBCSP)
electroencephalography
author_facet Attila Korik
Ronen Sosnik
Nazmul Siddique
Damien Coyle
author_sort Attila Korik
title Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot Study
title_short Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot Study
title_full Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot Study
title_fullStr Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot Study
title_full_unstemmed Decoding Imagined 3D Arm Movement Trajectories From EEG to Control Two Virtual Arms—A Pilot Study
title_sort decoding imagined 3d arm movement trajectories from eeg to control two virtual arms—a pilot study
publisher Frontiers Media S.A.
series Frontiers in Neurorobotics
issn 1662-5218
publishDate 2019-11-01
description Background: Realization of online control of an artificial or virtual arm using information decoded from EEG normally occurs by classifying different activation states or voluntary modulation of the sensorimotor activity linked to different overt actions of the subject. However, using a more natural control scheme, such as decoding the trajectory of imagined 3D arm movements to move a prosthetic, robotic, or virtual arm has been reported in a limited amount of studies, all using offline feed-forward control schemes.Objective: In this study, we report the first attempt to realize online control of two virtual arms generating movements toward three targets/arm in 3D space. The 3D trajectory of imagined arm movements was decoded from power spectral density of mu, low beta, high beta, and low gamma EEG oscillations using multiple linear regression. The analysis was performed on a dataset recorded from three subjects in seven sessions wherein each session comprised three experimental blocks: an offline calibration block and two online feedback blocks. Target classification accuracy using predicted trajectories of the virtual arms was computed and compared with results of a filter-bank common spatial patterns (FBCSP) based multi-class classification method involving mutual information (MI) selection and linear discriminant analysis (LDA) modules.Main Results: Target classification accuracy from predicted trajectory of imagined 3D arm movements in the offline runs for two subjects (mean 45%, std 5%) was significantly higher (p < 0.05) than chance level (33.3%). Nevertheless, the accuracy during real-time control of the virtual arms using the trajectory decoded directly from EEG was in the range of chance level (33.3%). However, the results of two subjects show that false-positive feedback may increase the accuracy in closed-loop. The FBCSP based multi-class classification method distinguished imagined movements of left and right arm with reasonable accuracy for two of the three subjects (mean 70%, std 5% compared to 50% chance level). However, classification of the imagined arm movement toward three targets was not successful with the FBCSP classifier as the achieved accuracy (mean 33%, std 5%) was similar to the chance level (33.3%). Sub-optimal components of the multi-session experimental paradigm were identified, and an improved paradigm proposed.
topic brain-computer interface (BCI)
imagined 3D arm movements
online motion trajectory prediction
multiple linear regression (mLR)
filter-bank common spatial Patterns (FBCSP)
electroencephalography
url https://www.frontiersin.org/article/10.3389/fnbot.2019.00094/full
work_keys_str_mv AT attilakorik decodingimagined3darmmovementtrajectoriesfromeegtocontroltwovirtualarmsapilotstudy
AT ronensosnik decodingimagined3darmmovementtrajectoriesfromeegtocontroltwovirtualarmsapilotstudy
AT nazmulsiddique decodingimagined3darmmovementtrajectoriesfromeegtocontroltwovirtualarmsapilotstudy
AT damiencoyle decodingimagined3darmmovementtrajectoriesfromeegtocontroltwovirtualarmsapilotstudy
_version_ 1724949916102426624