An Energy-Efficient Micropower Neural Recording Amplifier

Wattanapanitch, Woradorn; Fee, Michale S.; Sarpeshkar, Rahul

doi:10.1109/tbcas.2007.907868

Cited by 385 publications

(235 citation statements)

References 16 publications

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“…A figure of merit that captures the relationship between and power consumption in the amplifier is the noise efficiency factor (NEF) which was first introduced in [24] and captures the effective number of transistors contributing noise: (12) where is the total amplifier current, is the thermal voltage and is the bandwidth of the amplifier. Measured NEFs in state of the art low-noise amplifiers fall in between 2 and 3 [25]- [27]. For future analysis, a NEF of 3 will be used 8 and the required power for the array of amplifiers can then be calculated by rewriting (12) as (13) 7 The noise term due to the sampling switch of the S/H circuit has been omitted since it will be insignificant for any practical values of and .…”

Section: Otamentioning

confidence: 99%

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Design and Analysis of a Hardware-Efficient Compressed Sensing Architecture for Data Compression in Wireless Sensors

Chen

Chandrakasan

Stojanović

2012

IEEE J. Solid-State Circuits

335

222

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Abstract-This work introduces the use of compressed sensing (CS) algorithms for data compression in wireless sensors to address the energy and telemetry bandwidth constraints common to wireless sensor nodes. Circuit models of both analog and digital implementations of the CS system are presented that enable analysis of the power/performance costs associated with the design space for any potential CS application, including analog-to-information converters (AIC). Results of the analysis show that a digital implementation is significantly more energy-efficient for the wireless sensor space where signals require high gain and medium to high resolutions. The resulting circuit architecture is implemented in a 90 nm CMOS process. Measured power results correlate well with the circuit models, and the test system demonstrates continuous, on-the-fly data processing, resulting in more than an order of magnitude compression for electroencephalography (EEG) signals while consuming only 1.9 W at 0.6 V for sub-20 kS/s sampling rates. The design and measurement of the proposed architecture is presented in the context of medical sensors, however the tools and insights are generally applicable to any sparse data acquisition.

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Section: Otamentioning

confidence: 99%

“…The required value of varies by application and the expected dynamic range of the input signal, but a common specification used in previously published bio-sensor applications is 40 dB [3], [25], [27]. This constraint, however, assumes that the total gain is set such that the input range of the ADC is perfectly accommodated.…”

Section: Otamentioning

confidence: 99%

Design and Analysis of a Hardware-Efficient Compressed Sensing Architecture for Data Compression in Wireless Sensors

Chen

Chandrakasan

Stojanović

2012

IEEE J. Solid-State Circuits

335

222

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“…Many neural signal amplifiers have been developed since 2000 [8][9][10][11], but none of them meets our proposed needs. In former works, some authors implemented simple Operational Transconductance Amplifiers (OTA's) for neural signal amplification based on older technologies (1500 nm to 500 nm).…”

Section: B Neural Signal Amplifiersmentioning

confidence: 99%

Transmission of wireless neural signals through a 0.18µm CMOS low-power amplifier

Gazziro

Braga

Moreira

et al. 2015

2015 37th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

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Abstract-In the field of Brain Machine Interfaces (BMI) researchers still are not able to produce clinically viable solutions that meet the requirements of long-term operation without the use of wires or batteries. Another problem is neural compatibility with the electrode probes. One of the possible ways of approaching these problems is the use of semiconductor biocompatible materials (silicon carbide) combined with an integrated circuit designed to operate with low power consumption. This paper describes a low-power neural signal amplifier chip, named Cortex, fabricated using 0.18µm CMOS process technology with all electronics integrated in an area of 0.40mm 2 . The chip has 4 channels, total power consumption of only 144µW, and is impedance matched to silicon carbide biocompatible electrodes. I. INTRODUCTIONAlthough research with Brain Machine Interfaces (BMI) has evolved with great speed in recent years, researchers still do not have reliable BMI systems, which has prevented widespread clinical testing and, ultimately, assisting individuals with neurological and physical disabilities.In order for BMI to effectively make use of the advances in robotic and computer technology, it is vital to find a biological interface that meets the requirements of long-term electrical reliability, low-power operation, and biocompatibility. These requirements are of special importance. First, commonplace systems are based on batteries that eventually discharge and must be replaced after short periods of time, resulting in additional maintenance requirements; Second, many systems rely on materials that may not have reliable biocompatibility, and can possibly erode with time, demanding costly and high-risk replacement procedures [1][2]. In this paper, our contribution focuses on addressing these two issues.This project describes the development of a wireless BMI system -see Figure 1, with constraints of very low-power consumption and biocompatibility. Our solution relies on two features: (1) we use a chip designed to operate with a power consumption that is small enough for it to be powered by radio frequency antennas, dispensing with the need for batteries; (2) we use a probe manufactured from silicon carbide (SiC), a material that demonstrated excellent neural compatibility with murine mouse brain tissue in vivo [13]. This paper presents the first version of the Cortex chip, which is a 4-channel amplifier that magnifies neural signals to levels high enough for them to be processed by a computer. Fig. 1. Conceptual diagram of the proposed BMI system, which integrates the Cortex chip, described in detail in this paper, with cubic silicon carbide electrodes (3C-SiC) and an RFID wireless interface. II. CONCEPTS AND RELATED WORKS A. Gliosis and Neural ImplantsThe introduction of neural interfaces inside the central nervous system (CNS) inevitably damages the delicate tissue which leads to the neural inflammitory response, gliosis [1][2][3][4][5]. Gliosis is a reactive cellular process concerning physiological changes in glial cell...

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“…Other works [2] present better noise efficiency factor (NEF) but at the expense of more complex source-degenerated current mirrors architecture, which makes them more susceptible to process variations.…”

Section: Introductionmentioning

confidence: 99%

A Low Noise Low Power OTA with Adjustable Gain PID Feedback Network for EEG SoC Arrays"

Moreno¹,

Pimenta²,

Crepaldi³

et al. 2012

Biomedical Engineering - Technical Applications in Medicine

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An Energy-Efficient Micropower Neural Recording Amplifier

Cited by 385 publications

References 16 publications

Design and Analysis of a Hardware-Efficient Compressed Sensing Architecture for Data Compression in Wireless Sensors

Design and Analysis of a Hardware-Efficient Compressed Sensing Architecture for Data Compression in Wireless Sensors

Transmission of wireless neural signals through a 0.18µm CMOS low-power amplifier

A Low Noise Low Power OTA with Adjustable Gain PID Feedback Network for EEG SoC Arrays"

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An Energy-Efficient Micropower Neural Recording Amplifier

Cited by 385 publications

References 16 publications

Design and Analysis of a Hardware-Efficient Compressed Sensing Architecture for Data Compression in Wireless Sensors

Design and Analysis of a Hardware-Efficient Compressed Sensing Architecture for Data Compression in Wireless Sensors

Transmission of wireless neural signals through a 0.18&#x00B5;m CMOS low-power amplifier

A Low Noise Low Power OTA with Adjustable Gain PID Feedback Network for EEG SoC Arrays"

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Transmission of wireless neural signals through a 0.18µm CMOS low-power amplifier