A Bidirectional Neural Interface IC With Chopper Stabilized BioADC Array and Charge Balanced Stimulator

Greenwald, Elliot; So, Ernest; Wang, Qihong; Mollazadeh, Mohsen; Maier, Christoph; Etienne‐Cummings, Ralph; Cauwenberghs, Gert; Thakor, Nitish V.

doi:10.1109/tbcas.2016.2614845

Cited by 40 publications

(24 citation statements)

References 37 publications

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“…Compared to the SNDR expression from [28], in (8) we also include the linearity performance of the system. The assumption is that the THD is primarily dominated by the third order harmonic, which is a reasonable assumption for a differential architecture, but, also optimistic since it neglects the existence of other harmonics.…”

Section: Discussionmentioning

confidence: 99%

A 14-ENOB Delta-Sigma-Based Readout Architecture for ECoG Recording Systems

Ivanisevic

Rodriguez

Rusu

2018

IEEE Trans. Circuits Syst. I

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Abstract-This paper presents a delta-sigma based readout architecture targeting electrocortical recording in brain stimulation applications. The proposed architecture can accurately record a peak input signal up to 240 mV in a power-efficient manner without saturating or employing offset rejection techniques. The readout architecture consists of a delta-sigma modulator with an embedded analog front-end. The proposed architecture achieves a total harmonic distortion of -95 dB by employing a current-steering DAC and a multi-bit quantizer implemented as a tracking ADC. A system prototype is implemented in a 0.18 µm CMOS triple-well process and has a total power consumption of 54 µW. Measurement results, across ten packaged samples, show approximately 14-ENOB over a 300 Hz bandwidth with an input referred noise of 5.23 µVrms, power-supply/common-mode rejection ratio of 100 dB/98 dB and an input impedance larger than 94 MΩ.

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Section: Discussionmentioning

confidence: 99%

A 14-ENOB Delta-Sigma-Based Readout Architecture for ECoG Recording Systems

Ivanisevic

Rodriguez

Rusu

2018

IEEE Trans. Circuits Syst. I

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“…The recording channel is dedicated to performing proper amplification and filtration of weak input biomedical signals to optimally utilize allowable supply voltage and to condition signals for following blocks, such as analog to digital converters. There are many excellent examples of integrated electronics dedicated to biomedical signals recordings [27][28][29][30][31][32][33][34]. These very often utilize additional techniques to overcome problems with noise and power consumption (such as chopping, sigma-delta conversion, ad digital feedback), and promoted results are outstanding.…”

Section: Recording Channelmentioning

confidence: 99%

Highly Configurable 100 Channel Recording and Stimulating Integrated Circuit for Biomedical Experiments

Kmon

2021

Sensors

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This paper presents the design results of a 100-channel integrated circuit dedicated to various biomedical experiments requiring both electrical stimulation and recording ability. The main design motivation was to develop an architecture that would comprise not only the recording and stimulation, but would also block allowing to meet different experimental requirements. Therefore, both the controllability and programmability were prime concerns, as well as the main chip parameters uniformity. The recording stage allows one to set their parameters independently from channel to channel, i.e., the frequency bandwidth can be controlled in the (0.3 Hz–1 kHz)–(20 Hz–3 kHz) (slow signal path) or (0.3 Hz–1 kHz)–4.7 kHz (fast signal path) range, while the voltage gain can be set individually either to 43.5 dB or 52 dB. Importantly, thanks to in-pixel circuitry, main system parameters may be controlled individually allowing to mitigate the circuitry components spread, i.e., lower corner frequency can be tuned in the 54 dB range with approximately 5% precision, and the upper corner frequency spread is only 4.2%, while the voltage gain spread is only 0.62%. The current stimulator may also be controlled in the broad range (69 dB) with its current setting precision being no worse than 2.6%. The recording channels’ input-referred noise is equal to 8.5 µVRMS in the 10 Hz–4.7 kHz bandwidth. The single-pixel occupies 0.16 mm2 and consumes 12 µW (recording part) and 22 µW (stimulation blocks).

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“…The DC offset between two electrodes should be of concern as well, which is typically tens of millivolts [8,10,16], but is sometimes as large as 1-2 V [1,3,13]. To avoid saturation due to such a large offset, the recording system usually has the input stage of high-pass filtering, which may be dc-coupled with a feedback low-pass filter [9,12,15,16,20] or ac-coupled with an input capacitor [1][2][3][4][5][6][7][8][17][18][19][21][22][23][24][25][26][27][28]. Without additional power, the ac-coupled method is passive and easier to achieve.…”

Section: Introductionmentioning

confidence: 99%

A Fully Integrated 64-Channel Recording System for Extracellular Raw Neural Signals

Zhang

Chen

et al. 2021

Electronics

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This paper presents a fully integrated 64-channel neural recording system for local field potential and action potential. It mainly includes 64 low-noise amplifiers, 64 programmable amplifiers and filters, 9 switched-capacitor (SC) amplifiers, and a 10-bit successive approximation register analogue-to-digital converter (SAR ADC). Two innovations have been proposed. First, a two-stage amplifier with high-gain, rail-to-rail input and output, and dynamic current enhancement improves the speed of SC amplifiers. The second is a clock logic that can be used to align the switching clock of 64 channels with the sampling clock of ADC. Implemented in an SMIC 0.18 μm Complementary Metal Oxide Semiconductor (CMOS) process, the 64-channel system chip has a die area of 4 × 4 mm2 and is packaged in a QFN−88 of 10 × 10 mm2. Supplied by 1.8 V, the total power is about 8.28 mW. For each channel, rail-to-rail electrode DC offset can be rejected, the referred-to-input noise within 1 Hz–10 kHz is about 5.5 μVrms, the common-mode rejection ratio at 50 Hz is about 69 dB, and the output total harmonic distortion is 0.53%. Measurement results also show that multiple neural signals are able to be simultaneously recorded.

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A Bidirectional Neural Interface IC With Chopper Stabilized BioADC Array and Charge Balanced Stimulator

Cited by 40 publications

References 37 publications

A 14-ENOB Delta-Sigma-Based Readout Architecture for ECoG Recording Systems

A 14-ENOB Delta-Sigma-Based Readout Architecture for ECoG Recording Systems

Highly Configurable 100 Channel Recording and Stimulating Integrated Circuit for Biomedical Experiments

A Fully Integrated 64-Channel Recording System for Extracellular Raw Neural Signals

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