Low-noise Amplifier for Neural Recording
Low-noise Amplifier for Neural Recording

Author: Rachna Srivastava

Publisher:

Published: 2015

Total Pages: 72

ISBN-13:

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With a combination of engineering approaches and neurophysiological knowledge of the central nervous system, a new generation of medical devices is being developed to link groups of neurons with microelectronic systems. By doing this, researchers are acquiring fundamental knowledge of the mechanisms of disease and innovating treatments for disabilities in patients who have a failure of communication along neural pathways. A low-noise and low-power analog front-end circuit is one of the primary requirements for neural recording. The main function for the front-end amplifier is to provide gain over the bandwidth of neural signals and to reject undesired frequency components. The chip developed in this thesis is a field-programmable analog front-end amplifier consisting of 16 programmable channels with tunable frequency response. A capacitively coupled two-stage amplifier is used. The first-stage amplifier is a Low-Noise Amplifier (LNA), as it directly interfaces with the neural recording micro-electrodes; the second stage is a high gain and high swing amplifier. A MOS resistor in the feedback path is used to get tunable low-cut-off frequency and reject the dc offset voltage. Our design builds upon previous recording chips designed by two former graduate stu- dents in our lab. In our design, the circuits are optimized for low noise. Our simulations show the recording channel has a gain of 77.9 dB and input-referred noise of 6.95 [mu]V rms(Root-Mean-Square voltage) over 750 Hz to 6.9 kHz. The chip is fabricated in AMS 0.35 [mu]m CMOS technology for a total die area of 3 x 3 mm 2 and Total Power Dissipation (TPD) of 2.9 mW. To verify the functionality and adherence to the design specifications it will be tested on Printed-Circuit-Board.

Ultra Low-Power Integrated Circuit Design for Wireless Neural Interfaces
Ultra Low-Power Integrated Circuit Design for Wireless Neural Interfaces

Author: Jeremy Holleman

Publisher: Springer Science & Business Media

Published: 2010-10-29

Total Pages: 123

ISBN-13: 1441967273

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This book will describe ultra low-power, integrated circuits and systems designed for the emerging field of neural signal recording and processing, and wireless communication. Since neural interfaces are typically implanted, their operation is highly energy-constrained. This book introduces concepts and theory that allow circuit operation approaching the fundamental limits. Design examples and measurements of real systems are provided. The book will describe circuit designs for all of the critical components of a neural recording system, including: Amplifiers which utilize new techniques to improve the trade-off between good noise performance and low power consumption. Analog and mixed-signal circuits which implement signal processing tasks specific to the neural recording application: Detection of neural spikes Extraction of features that describe the spikes Clustering, a machine learning technique for sorting spikes Weak-inversion operation of analog-domain transistors, allowing processing circuits that reduce the requirements for analog-digital conversion and allow low system-level power consumption. Highly-integrated, sub-mW wireless transmitter designed for the Medical Implant Communications Service (MICS) and ISM bands.

Multichannel Neural Recording for Implantable Neuroprosthetics
Multichannel Neural Recording for Implantable Neuroprosthetics

Author: Hua Rong

Publisher: LAP Lambert Academic Publishing

Published: 2011-05

Total Pages: 72

ISBN-13: 9783844398946

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Integrated, low-power, low-noise CMOS neural amplifiers have recently grown in importance as large microelectrode arrays have begun to be practical. This project aims to design a low power, low noise and low THD adjustable gain neural amplifier for multichannel neural recording chip for use with cuff-based recording microelectrodes. The neural amplifier is designed using AMS CS 0.35um technology for supply voltage of 3V. With overall power consumption less than 0.5mW, it is able to measure three different types of neural signal with adjustable gain between 50 to 10000 and bandwidth vary from few hundred hertz up to 10kHz. The input- referred noises are below 45nV/sqrt(Hz) at 1kHz in all the three different signals cases. THD varies as the gain changes, in general lower the gain will have better the THD. Two different neural amplifier topologies (single op- amp and two op-amp) have been designed and simulated separately in CADENCE for three different gains situations. It was found that the two op-amp topology design has better overall performance than the single op-amp design despite it is more power consuming.

An Ultra-low-power Neural Recording Amplifier and Its Use in Adaptively-biased Multi-amplifier Arrays
An Ultra-low-power Neural Recording Amplifier and Its Use in Adaptively-biased Multi-amplifier Arrays

Author: Woradorn Wattanapanitch

Publisher:

Published: 2007

Total Pages: 101

ISBN-13:

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(cont.) Finally, the adaptive biasing technique is discussed. The design and the detailed analysis of a feedback calibration loop for adjusting the input-referred noise of the amplifier based on the information extracted from the recording site's background noise is also presented. With such an adaptive biasing scheme, significant power savings in a multi-electrode array may be achieved since each amplifier operates with just enough power such that its input-referred noise is significantly but not overly below the neural noise.

Tunable Low-Power Low-Noise Amplifier for Healthcare Applications
Tunable Low-Power Low-Noise Amplifier for Healthcare Applications

Author: Rafael Vieira

Publisher: Springer Nature

Published: 2021-03-19

Total Pages: 88

ISBN-13: 303070887X

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This book consists of the research, design and implementation, from sizing to layout with parasitic extraction and yield estimation, of a low-power, low-noise amplifier for biomedical and healthcare applications of bio-potential signals, particularly focusing on the electromyography and electrooculography. These signals usually operate in different broadbands, yet follow an impulse-shape transmission, hence being suitable to be applied and detected by the same receiver.

Wireless Power Transfer and Data Communication for Neural Implants
Wireless Power Transfer and Data Communication for Neural Implants

Author: Gürkan Yilmaz

Publisher: Springer

Published: 2017-01-01

Total Pages: 119

ISBN-13: 331949337X

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This book presents new circuits and systems for implantable biomedical applications targeting neural recording. The authors describe a system design adapted to conform to the requirements of an epilepsy monitoring system. Throughout the book, these requirements are reflected in terms of implant size, power consumption, and data rate. In addition to theoretical background which explains the relevant technical challenges, the authors provide practical, step-by-step solutions to these problems. Readers will gain understanding of the numerical values in such a system, enabling projections for feasibility of new projects.

A Multi Channel Chopper Modulated Neural Recording System
A Multi Channel Chopper Modulated Neural Recording System

Author:

Publisher:

Published: 2001

Total Pages: 0

ISBN-13:

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Presented herein is a fully integrated low-noise CMOS multi-channel amplifier for neural recording applications The circuit employs the chopper modulation technique to reduce the effect of flicker noise and DC offset, A reduced area design implementation is achieved by trading off the increased noise margin performance of the chopper modulator for minimal amplifier area and analog multiplexing of the recording sites, A fully differential topology is used for the signal path to improve noise immunity The analog amplifier exhibits 56 dB of gain with a 115 kHz bandwidth and a common mode rejection ratio (CMRR) of 80 dB. Simulation results show a total input referred noise less than 16 nV/square root of Hz, The system power consumption is approximately 750 microWatts The fully integrated system was designed in ABN 1,6-um single poly n-well CMOS process.

Circuit Design Considerations for Implantable Devices
Circuit Design Considerations for Implantable Devices

Author: Peng Cong

Publisher: CRC Press

Published: 2022-09-01

Total Pages: 210

ISBN-13: 100079461X

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Implantable devices are a unique area for circuit designers. A comprehensive understanding of design trade-offs at the system level is important to ensure device success. Circuit Design Considerations for Implantable Devices provides knowledge to CMOS circuit designers with limited biomedical background to understand design challenges and trade-offs for implantable devices, especially neural interfacing.Technical topics discussed in the book include: Neural interface  Neural sensing amplifiers  Electrical stimulation  Embedded Signal Analysis Wireless Power Transmission to mm-Sized Free-Floating Distributed Implants Next Generation Neural Interface Electronics

An Ultra Low Power Implantable Neural Recording System for Brain-machine Interfaces
An Ultra Low Power Implantable Neural Recording System for Brain-machine Interfaces

Author: Woradorn Wattanapanitch

Publisher:

Published: 2011

Total Pages: 187

ISBN-13:

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In the past few decades, direct recordings from different areas of the brain have enabled scientists to gradually understand and unlock the secrets of neural coding. This scientific advancement has shown great promise for successful development of practical brain-machine interfaces (BMIs) to restore lost body functions to patients with disorders in the central nervous system. Practical BMIs require the uses of implantable wireless neural recording systems to record and process neural signals, before transmitting neural information wirelessly to an external device, while avoiding the risk of infection due to through-skin connections. The implantability requirement poses major constraints on the size and total power consumption of the neural recording system. This thesis presents the design of an ultra-low-power implantable wireless neural recording system for use in brain-machine interfaces. The system is capable of amplifying and digitizing neural signals from 32 recording electrodes, and processing the digitized neural data before transmitting the neural information wirelessly to a receiver at a data rate of 2.5 Mbps. By combining state-of-the-art custom ASICs, a commercially-available FPGA, and discrete components, the system achieves excellent energy efficiency, while still offering design flexibility during the system development phase. The system's power consumption of 6.4 mW from a 3.6-V supply at a wireless output data rate of 2.5 Mbps makes it the most energy-efficient implantable wireless neural recording system reported to date. The system is integrated on a flexible PCB platform with dimensions of 1.8 cm x 5.6 cm and is designed to be powered by an implantable Li-ion battery. As part of this thesis, I describe the design of low-power integrated circuits (ICs) for amplification and digitization of the neural signals, including a neural amplifier and a 32-channel neural recording IC. Low-power low-noise design techniques are utilized in the design of the neural amplifier such that it achieves a noise efficiency factor (NEF) of 2.67, which is close to the theoretical limit determined by physics. The neural recording IC consists of neural amplifiers, analog multiplexers, ADCs, serial programming interfaces, and a digital processing unit. It can amplify and digitize neural signals from 32 recording electrodes, with a sampling rate of 31.25 kS/s per channel, and send the digitized data off-chip for further processing. The IC was successfully tested in an in-vivo wireless recording experiment from a behaving primate with an average power dissipation per channel of 10.1 [mu]W. Such a system is also widely useful in implantable brain-machine interfaces for the blind and paralyzed, and in cochlea implants for the deaf.