A Fully Integrated 11.2-mm2 a-IGZO EMG Front-End Circuit on Flexible Substrate Achieving Up to 41-dB SNR and 29-M[Formula Omitted] Input Impedance

A biopotential front-end (FE) circuit is designed and fabricated using amorphous indium-gallium-zinc-oxide (a-IGZO) TFTs on flexible plastic substrate. Its input chopper provides both noise reduction and frequency division multiplexing among multiple FEs in an array. Measurements of the FE at choppi...

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Bibliographic Details
Published in:IEEE solid-state circuits letters 2018-01, Vol.1 (6), p.142
Main Authors: Garripoli, Carmine, Abdinia, Sahel, Jan-Laurens J P van der Steen, Gelinck, Gerwin H, Cantatore, Eugenio
Format: Article
Language:English
Subjects:
Circuit design
Cutting
Foils
Forearm
Frequency division multiplexing
Gallium
Indium gallium zinc oxide
Input impedance
Muscles
Noise levels
Noise reduction
Power consumption
Spatial resolution
Substrates
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Summary:A biopotential front-end (FE) circuit is designed and fabricated using amorphous indium-gallium-zinc-oxide (a-IGZO) TFTs on flexible plastic substrate. Its input chopper provides both noise reduction and frequency division multiplexing among multiple FEs in an array. Measurements of the FE at chopping frequencies from 5 to 8 kHz show a gain in the range of 24.9–23.1 dB, bandwidth of 5.4–5.2 kHz, input noise in the EMG band ranging from [Formula Omitted] to [Formula Omitted], and an input impedance of 29.6–23 [Formula Omitted]. At different chopping frequencies, the SNR in the EMG band is respectively, 29, 32.3, 38, and 41 dB, enough to monitor muscle fiber conduction velocity. This is achieved in a total area of 11.2 mm2 and with 1.3-mW power consumption. In-vivo recordings of EMG from the forearm of a person using the fabricated FE and standard gel electrodes have been performed. The measurements show EMG bursts with a maximum amplitude of 1.6 mV, which is within the physiological range for this muscle. The proposed circuit achieves an [Formula Omitted] reduction in size compared to previous FEs fabricated on flexible foil for EMG applications, enabling a spatial resolution in the order of a few millimeters, with great benefit for the diagnosis of neuromuscular disorders.
ISSN:2573-9603
DOI:10.1109/LSSC.2018.2878184