1 |
Development and validation of a low noise signal acquisition protocol for inner ear evoked potentialsKumaragamage, Chathura Lahiru 07 1900 (has links)
A low noise signal acquisition protocol is required for inner ear evoked response
recordings. In this work, a parallel amplifier approach was investigated to implement a
bio-signal amplifier with low voltage noise (<5nV/√Hz), and low current noise
(~2fA/√Hz). A modified ear electrode was investigated to reduce biological interference
and thermal noise due to high impedance electrodes. A physical model to simulate
electrical activity of the inner ear was developed to evaluate the accuracy of detecting
vestibular field potentials (FPs) in the presence of various noise sources. Muscle activity
and noise generated from the recording apparatus were found to be the dominating
sources, degrading performance of FP extraction.
Contributions from this work include: the design, implementation, and validation of a
bio-signal amplifier with <5nV/√Hz voltage noise, and a low impedance electrode
development and placement protocol. As a result, a signal-to-noise-ratio improvement of
~11dB (compared to the current protocol) was achieved.
|
2 |
Development and validation of a low noise signal acquisition protocol for inner ear evoked potentialsKumaragamage, Chathura Lahiru 07 1900 (has links)
A low noise signal acquisition protocol is required for inner ear evoked response
recordings. In this work, a parallel amplifier approach was investigated to implement a
bio-signal amplifier with low voltage noise (<5nV/√Hz), and low current noise
(~2fA/√Hz). A modified ear electrode was investigated to reduce biological interference
and thermal noise due to high impedance electrodes. A physical model to simulate
electrical activity of the inner ear was developed to evaluate the accuracy of detecting
vestibular field potentials (FPs) in the presence of various noise sources. Muscle activity
and noise generated from the recording apparatus were found to be the dominating
sources, degrading performance of FP extraction.
Contributions from this work include: the design, implementation, and validation of a
bio-signal amplifier with <5nV/√Hz voltage noise, and a low impedance electrode
development and placement protocol. As a result, a signal-to-noise-ratio improvement of
~11dB (compared to the current protocol) was achieved.
|
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