Your search keyword '"Jinghom Chakhap"' showing total 2 results

1. Using conductive fabric for capacitive EEG measurements

Author

Jinghom Chakhap, Yue-Der Lin, Yen-Ting Lin, and Ya-Wen Tang

Subjects

medicine.diagnostic_test, business.industry, Computer science, Capacitive sensing, Acoustics, Frequency domain, Electrical engineering, medicine, Electrical and Electronic Engineering, Electroencephalography, business, Electrical conductor, Eeg monitoring

Abstract

Traditional electroencephalogram (EEG) measurements require conductive gel to ensure good conduction between the electrodes and skin (or scalp). But this gel may make patients uncomfortable because of possible skin allergies during long-term measurement. The measurement procedure is also tedious because pasting the electrodes to the patient’s scalp is time consuming. The required lead wires also constrain patient movements. This study uses conductive fabric as the capacitive electrode for EEG measurements. This paper provides the design considerations and the related theoretical analysis for this method. A long-term, null-input experiment was conducted to verify the stability of the proposed system. Experiments were conducted over the hair of patients to verify the feasibility of using the method during EEG monitoring. Various mental task experiments were also conducted. The changes in frequency domain analysis show that the proposed strategy discriminates between different mental tasks.

Published

2013

2. Using Conductive Fabric for Capacitive EEG Measurements.

Author

Ya-Wen Tang, Yue-Der Lin, Yen-Ting Lin, and Jinghom Chakhap

Subjects

ELECTROENCEPHALOGRAPHY, ELECTRODES, SCALP, BIOMEDICAL signal processing, DIGITAL images

Abstract

Traditional electroencephalogram (EEG) measurements require conductive gel to ensure good conduction between the electrodes and skin (or scalp). But this gel may make patients uncomfortable because of possible skin allergies during long-term measurement. The measurement procedure is also tedious because pasting the electrodes to the patient's scalp is time consuming. The required lead wires also constrain patient movements. This study uses conductive fabric as the capacitive electrode for EEG measurements. This paper provides the design considerations and the related theoretical analysis for this method. A long-term, null-input experiment was conducted to verify the stability of the proposed system. Experiments were conducted over the hair of patients to verify the feasibility of using the method during EEG monitoring. Various mental task experiments were also conducted. The changes in frequency domain analysis show that the proposed strategy discriminates between different mental tasks. [ABSTRACT FROM AUTHOR]

Published

2013