Finger joint reconstruction from electroencephalography signals with deep learning
Brain-Computer Interface (BCI) is an important technique for robot control and rehabilitation. Motion Trajectory Prediction BCI (MTP-BCI) is considered suitable for high-precision tasks by decoding continuous motion information from Electroencephalography (EEG) signals. While numerous studies ha...
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2023
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sg-ntu-dr.10356-1719952023-11-24T15:36:53Z Finger joint reconstruction from electroencephalography signals with deep learning Tang Yuting Guan Cuntai School of Computer Science and Engineering Center for Brain-Computing Research Robinson Neethu CTGuan@ntu.edu.sg, nrobinson@ntu.edu.sg Engineering::Computer science and engineering::Computer applications::Computer-aided engineering Science::Medicine::Computer applications Brain-Computer Interface (BCI) is an important technique for robot control and rehabilitation. Motion Trajectory Prediction BCI (MTP-BCI) is considered suitable for high-precision tasks by decoding continuous motion information from Electroencephalography (EEG) signals. While numerous studies have focused on reconstructing the kinematics of upper and lower limbs, there is a dearth of updated research on finger movement reconstruction, particularly in non-invasive settings, despite its critical role in daily tasks. Utilizing deep learning neural networks, this study aims to reconstruct finger joint angles from EEG signals in a non-invasive setting. The models are rigorously evaluated on a novel dataset comprising 20 healthy subjects, and Explainable AI (XAI) algorithms are employed to interpret the parameters of the trained models. The findings demonstrate the feasibility of MTP-BCI for finger movement, potentially offering insights for asynchronous BCI and the development of new BCI commands. Additionally, this study is investigating the use of Motor Execution (ME) decoders on Motor Imagery (MI) data to decode imagery movement kinematics, based on neuroscience findings indicating overlaps between cortical regions related to motor imagery and execution. Future efforts will focus on: • assessing decoder robustness, particularly in rest state • enhancing ME decoding performance • designing a novel neural network architecture for continuous movement signal decoding This study is targeting to be submitted to the 46th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, 2024. Updates on progress, findings, and paper drafts will be continuously included into revised versions of this report. Bachelor of Engineering (Computer Science) 2023-11-20T05:14:41Z 2023-11-20T05:14:41Z 2023 Final Year Project (FYP) Tang Yuting (2023). Finger joint reconstruction from electroencephalography signals with deep learning. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/171995 https://hdl.handle.net/10356/171995 en SCSE22-1122 application/pdf Nanyang Technological University |
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Engineering::Computer science and engineering::Computer applications::Computer-aided engineering Science::Medicine::Computer applications Tang Yuting Finger joint reconstruction from electroencephalography signals with deep learning |
| description |
Brain-Computer Interface (BCI) is an important technique for robot control and
rehabilitation. Motion Trajectory Prediction BCI (MTP-BCI) is considered suitable
for high-precision tasks by decoding continuous motion information from
Electroencephalography (EEG) signals.
While numerous studies have focused on reconstructing the kinematics of
upper and lower limbs, there is a dearth of updated research on finger movement
reconstruction, particularly in non-invasive settings, despite its critical role in
daily tasks.
Utilizing deep learning neural networks, this study aims to reconstruct finger
joint angles from EEG signals in a non-invasive setting. The models are rigorously
evaluated on a novel dataset comprising 20 healthy subjects, and Explainable AI
(XAI) algorithms are employed to interpret the parameters of the trained models.
The findings demonstrate the feasibility of MTP-BCI for finger movement,
potentially offering insights for asynchronous BCI and the development of new
BCI commands. Additionally, this study is investigating the use of Motor Execution
(ME) decoders on Motor Imagery (MI) data to decode imagery movement
kinematics, based on neuroscience findings indicating overlaps between cortical
regions related to motor imagery and execution.
Future efforts will focus on:
• assessing decoder robustness, particularly in rest state
• enhancing ME decoding performance
• designing a novel neural network architecture for continuous movement signal
decoding
This study is targeting to be submitted to the 46th Annual International Conference
of the IEEE Engineering in Medicine and Biology Society, 2024. Updates
on progress, findings, and paper drafts will be continuously included into revised
versions of this report. |
| author2 |
Guan Cuntai |
| author_facet |
Guan Cuntai Tang Yuting |
| format |
Final Year Project |
| author |
Tang Yuting |
| author_sort |
Tang Yuting |
| title |
Finger joint reconstruction from electroencephalography signals with deep learning |
| title_short |
Finger joint reconstruction from electroencephalography signals with deep learning |
| title_full |
Finger joint reconstruction from electroencephalography signals with deep learning |
| title_fullStr |
Finger joint reconstruction from electroencephalography signals with deep learning |
| title_full_unstemmed |
Finger joint reconstruction from electroencephalography signals with deep learning |
| title_sort |
finger joint reconstruction from electroencephalography signals with deep learning |
| publisher |
Nanyang Technological University |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/171995 |
| _version_ |
1783955499376443392 |