Design strategies for multi-channel low-noise recording systems

Rieger, Robert; Taylor, J.

doi:10.1007/s10470-008-9230-5

Cited by 24 publications

(9 citation statements)

References 49 publications

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“…The power consumption is simulated as 1.2 W ( V supply) and 2 W ( V supply). In the current setup the amplifier power remains negligible compared to the power consumed by the microcontroller of about 300 W. The estimated input-referred spot-noise density is 157 nV/ Hz, on an order comparable with recent low-power designs [22], [23].…”

Section: Integrated Variable Gain Amplifiersupporting

confidence: 57%

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Double-Differential Recording and AGC Using Microcontrolled Variable Gain ASIC

Rieger

Deng

2013

IEEE Trans. Neural Syst. Rehabil. Eng.

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Abstract-Low-power wearable recording of biopotentials requires acquisition front-ends with high common-mode rejection for interference suppression and adjustable gain to provide an optimum signal range to a cascading analogue-to-digital stage. A microcontroller operated double-differential (DD) recording setup and automatic gain control circuit (AGC) are discussed which reject common-mode interference and provide tunable gain, thus compensating for imbalance and variation in electrode interface impedance. Custom-designed variable gain amplifiers (ASIC) are used as part of the recording setup. The circuit gain and balance is set by the timing of microcontroller generated clock signals. Measured results are presented which confirm that improved common-mode rejection is achieved compared to a single differential amplifier in the presence of input network imbalance. Practical measured examples further validate gain control suitable for biopotential recording and power-line rejection for wearable ECG and EMG recording. The prototype front-end consumes 318 W including amplifiers and microcontroller.

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Section: Integrated Variable Gain Amplifiersupporting

confidence: 57%

“…It trades off with lower input impedance in the range of 100 k , decreasing the effective resistance . In applications that require higher input impedance MOSFET transistors may be used but with potentially higher noise levels [23]. The integrator consists of a differential amplifier with feedback capacitors [24].…”

Section: Integrated Variable Gain Amplifiermentioning

confidence: 99%

Double-Differential Recording and AGC Using Microcontrolled Variable Gain ASIC

Rieger

Deng

2013

IEEE Trans. Neural Syst. Rehabil. Eng.

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“…Although the required amplifier bandwidth varies for different biomedical applications, low-frequency operation not exceeding a few tens of kilohertz is a typical specification [20][21][22]. Generally, the preamplifier determines the signal-to-noise-ratio (SNR) of the signal processing chain [23]. Noise entering after the initial signal amplification becomes less detrimental.…”

Section: Introductionmentioning

confidence: 99%

“…Reliable suppression of electrode offset voltages before amplification becomes essential to maintain appropriate dynamic range, and it presents a major design challenge. The review presented in [23] indicates that it is not uncommon to spend over 30% of the total power budget on pre-amplification to meet the tight noise requirements. The power budget is ultimately limited by the resulting heat generation, which must not cause any tissue damage.…”

Section: Introductionmentioning

confidence: 99%

“…The values are further supported by data from an extensive review of publications presented in Section 3. A CMOS input stage provides a good trade-off between high input impedance, high gain, low power consumption, and reasonable manufacturing costs [23]. However, the noise of a MOS field-effect transistor is dominated at low frequencies by its high intrinsic flicker noise.…”

Section: Introductionmentioning

confidence: 99%

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Noise Efficient Integrated Amplifier Designs for Biomedical Applications

2021

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The recording of neural signals with small monolithically integrated amplifiers is of high interest in research as well as in commercial applications, where it is common to acquire 100 or more channels in parallel. This paper reviews the recent developments in low-noise biomedical amplifier design based on CMOS technology, including lateral bipolar devices. Seven major circuit topology categories are identified and analyzed on a per-channel basis in terms of their noise-efficiency factor (NEF), input-referred absolute noise, current consumption, and area. A historical trend towards lower NEF is observed whilst absolute noise power and current consumption exhibit a widespread over more than five orders of magnitude. The performance of lateral bipolar transistors as amplifier input devices is examined by transistor-level simulations and measurements from five different prototype designs fabricated in 180 nm and 350 nm CMOS technology. The lowest measured noise floor is 9.9 nV/√Hz with a 10 µA bias current, which results in a NEF of 1.2.

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