TY - GEN
T1 - EEG-Based Classification of Passive Pedaling Speeds Using SVM
T2 - 4th Latin American Workshop on Computational Neuroscience, LAWCN 2023
AU - Blanco-Diaz, Cristian Felipe
AU - Guerrero-Mendez, Cristian David
AU - Gonzalez-Cely, Aura Ximena
AU - Ruiz-Olaya, Andrés Felipe
AU - Delisle-Rodriguez, Denis
AU - Bastos-Filho, Teodiano
AU - Jaramillo-Isaza, Sebastián
N1 - Publisher Copyright:
© The Author(s), under exclusive license to Springer Nature Switzerland AG 2024.
PY - 2024
Y1 - 2024
N2 - Motorized Mini Exercise Bikes (MMEBs), have found applications in Brain Computer Interfaces (BCIs) for rehabilitation, aiming to enhance neural plasticity and restore limb movements. However, processing electroencephalography (EEG) data in this context presents challenges, often relying on discrete on/off control strategies. Such limitations can impact rehabilitation progress and Human-Machine Interaction (HMI). This study introduces a Support Vector Machine (SVM)-based approach to classify passive pedaling tasks at varying speeds using EEG signals. The research protocol involved four healthy volunteers performing passive pedaling induced by a MMEB at two speeds: 30 and 60 rpm. SVM achieved an average ACC of 0.77, a false positive rate of 0.26, and AUC of 0.80, demonstrating the feasibility of accurately identifying passive pedaling at both low and high speeds using EEG signals. These results hold promising implications for improving the design of more robust and adaptive controllers in BCI systems integrated with MMEBs, particularly within the context of lower limb rehabilitation. This research supports the way for enhanced brain-machine interaction, offering potential benefits to individuals with disabilities by facilitating more precise control of rehabilitation devices and advancing the field of neuroengineering. Further exploration of real-world applications and broader implications is necessary to fully harness the potential of this SVM-based approach.
AB - Motorized Mini Exercise Bikes (MMEBs), have found applications in Brain Computer Interfaces (BCIs) for rehabilitation, aiming to enhance neural plasticity and restore limb movements. However, processing electroencephalography (EEG) data in this context presents challenges, often relying on discrete on/off control strategies. Such limitations can impact rehabilitation progress and Human-Machine Interaction (HMI). This study introduces a Support Vector Machine (SVM)-based approach to classify passive pedaling tasks at varying speeds using EEG signals. The research protocol involved four healthy volunteers performing passive pedaling induced by a MMEB at two speeds: 30 and 60 rpm. SVM achieved an average ACC of 0.77, a false positive rate of 0.26, and AUC of 0.80, demonstrating the feasibility of accurately identifying passive pedaling at both low and high speeds using EEG signals. These results hold promising implications for improving the design of more robust and adaptive controllers in BCI systems integrated with MMEBs, particularly within the context of lower limb rehabilitation. This research supports the way for enhanced brain-machine interaction, offering potential benefits to individuals with disabilities by facilitating more precise control of rehabilitation devices and advancing the field of neuroengineering. Further exploration of real-world applications and broader implications is necessary to fully harness the potential of this SVM-based approach.
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U2 - 10.1007/978-3-031-63848-0_1
DO - 10.1007/978-3-031-63848-0_1
M3 - Conference contribution
AN - SCOPUS:85199176627
SN - 9783031638473
T3 - Communications in Computer and Information Science
SP - 3
EP - 13
BT - Computational Neuroscience - 4th Latin American Workshop, LAWCN 2023, Revised Selected Papers
A2 - Riascos Salas, Jaime A.
A2 - Villota, Hernán
A2 - Betancur Vasquez, Daniel
A2 - Cota, Vinícius Rosa
PB - Springer Science and Business Media Deutschland GmbH
Y2 - 28 November 2023 through 30 November 2023
ER -