Mixed-Signal Compensation of Tripolar Cuff Electrode Imbalance in a Low-Noise ENG Analog Front-End
Due to their low amplitude, electroneurogram (ENG) signals are particularly subject to external muscle artefacts and intrinsic electronic noise. However, achieving a high signal-to-noise ratio is a challenge for implanted systems that have a limited power budget. This work presents a low-power analo...
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| Published in | ESSCIRC 2022- IEEE 48th European Solid State Circuits Conference (ESSCIRC) pp. 445 - 448 |
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| Main Authors | , |
| Format | Conference Proceeding |
| Language | English |
| Published |
IEEE
19.09.2022
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| Subjects | |
| Online Access | Get full text |
| DOI | 10.1109/ESSCIRC55480.2022.9911326 |
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| Abstract | Due to their low amplitude, electroneurogram (ENG) signals are particularly subject to external muscle artefacts and intrinsic electronic noise. However, achieving a high signal-to-noise ratio is a challenge for implanted systems that have a limited power budget. This work presents a low-power analog front-end which features low intrinsic noise and high interference rejection. The proposed mixed-signal feedback loop for tripolar cuff electrode imbalance compensation provides an interference rejection of 56 dB with a negligible power overhead. The instrumentation amplifier achieves a gain of 91.5 dB, an input-referred noise of 1.35 µV, an input offset voltage below 1 µV, and digitally-tunable imbalance compensation with 7 bits of resolution over a ±20 % range. The results are validated on the ICare microcontroller system-on-chip, a 22-nm fully-depleted silicon-on-insulator prototype. |
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| AbstractList | Due to their low amplitude, electroneurogram (ENG) signals are particularly subject to external muscle artefacts and intrinsic electronic noise. However, achieving a high signal-to-noise ratio is a challenge for implanted systems that have a limited power budget. This work presents a low-power analog front-end which features low intrinsic noise and high interference rejection. The proposed mixed-signal feedback loop for tripolar cuff electrode imbalance compensation provides an interference rejection of 56 dB with a negligible power overhead. The instrumentation amplifier achieves a gain of 91.5 dB, an input-referred noise of 1.35 µV, an input offset voltage below 1 µV, and digitally-tunable imbalance compensation with 7 bits of resolution over a ±20 % range. The results are validated on the ICare microcontroller system-on-chip, a 22-nm fully-depleted silicon-on-insulator prototype. |
| Author | Bol, David Dekimpe, Remi |
| Author_xml | – sequence: 1 givenname: Remi surname: Dekimpe fullname: Dekimpe, Remi email: remi.dekimpe@uclouvain.be organization: ICTEAM institute, Université catholique de Louvain (UCLouvain),Louvain-la-Neuve,Belgium – sequence: 2 givenname: David surname: Bol fullname: Bol, David email: david.bol@uclouvain.be organization: ICTEAM institute, Université catholique de Louvain (UCLouvain),Louvain-la-Neuve,Belgium |
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| Snippet | Due to their low amplitude, electroneurogram (ENG) signals are particularly subject to external muscle artefacts and intrinsic electronic noise. However,... |
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| SubjectTerms | analog front-end Biomedical electronics CMOS integrated circuits Electrodes electroneurogram imbalance Interference low noise Prototypes Silicon-on-insulator Solid state circuits System-on-chip Voltage |
| Title | Mixed-Signal Compensation of Tripolar Cuff Electrode Imbalance in a Low-Noise ENG Analog Front-End |
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