TY - JOUR
T1 - A novel signal processing method using system identification for underwater surface electromyography
AU - Uehara, S.
AU - Muraoka, Y.
AU - Tanabe, S.
AU - Ota, T.
AU - Kimura, A.
PY - 2009/3
Y1 - 2009/3
N2 - Purpose: Currently, to record underwater surface electromyography (EMG), electrodes are covered with water-proof tape. For short-term measurement, waterproof tape prevents electrical leakage. However, during long-term measurement, water or sweat can contact the electrodes, changing the measurement conditions and gradually affecting the EMG data. The purpose of present study was to devise a novel method for prolonged underwater EMG recording, which estimate dry-land EMG from underwater EMG recorded by non-waterproofed electrodes using system identification techniques. Method: One healthy male participated in this study. System identification was used to convert underwater EMG signals to the estimated dry-land signals. Transfer functions were derived using two pairs of surface recording electrodes on the same muscle in parallel. System input was the EMG recorded using non-waterproofed electrodes; the output was the signal recorded underwater using waterproofed electrodes (supposed to be the same as dry-land signals). To examine the validity of the present method, three experiments were conducted. Result: There was a high positive correlation between the estimated dry-land EMG based on the non-water-proofed electrodes and the EMG obtained using waterproofed electrodes. To test the validity of long-term recording using the novel method, the estimated dry-land EMG signals were measured during 30 minutes of underwater stepping and were stable. Conclusion: The novel method using non-waterproofed electrodes with system identification techniques eliminated the effect of changes in measurement conditions and appears effective for long-term, underwater surface EMG recording.
AB - Purpose: Currently, to record underwater surface electromyography (EMG), electrodes are covered with water-proof tape. For short-term measurement, waterproof tape prevents electrical leakage. However, during long-term measurement, water or sweat can contact the electrodes, changing the measurement conditions and gradually affecting the EMG data. The purpose of present study was to devise a novel method for prolonged underwater EMG recording, which estimate dry-land EMG from underwater EMG recorded by non-waterproofed electrodes using system identification techniques. Method: One healthy male participated in this study. System identification was used to convert underwater EMG signals to the estimated dry-land signals. Transfer functions were derived using two pairs of surface recording electrodes on the same muscle in parallel. System input was the EMG recorded using non-waterproofed electrodes; the output was the signal recorded underwater using waterproofed electrodes (supposed to be the same as dry-land signals). To examine the validity of the present method, three experiments were conducted. Result: There was a high positive correlation between the estimated dry-land EMG based on the non-water-proofed electrodes and the EMG obtained using waterproofed electrodes. To test the validity of long-term recording using the novel method, the estimated dry-land EMG signals were measured during 30 minutes of underwater stepping and were stable. Conclusion: The novel method using non-waterproofed electrodes with system identification techniques eliminated the effect of changes in measurement conditions and appears effective for long-term, underwater surface EMG recording.
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M3 - Article
C2 - 19400405
AN - SCOPUS:63049113431
SN - 0301-150X
VL - 49
SP - 103
EP - 108
JO - Electromyography and Clinical Neurophysiology
JF - Electromyography and Clinical Neurophysiology
IS - 2-3
ER -