Active Electrodes for Wearable EEG Acquisition: Review and Electronics Design Methodology

Xu, Jiawei; Mitra, Srinjoy; Hoof, Chris Van; Yazıcıoğlu, Refet Fırat; Makinwa, Kofi A. A.

doi:10.1109/rbme.2017.2656388

Cited by 139 publications

(76 citation statements)

References 65 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Due to its unprecedentedly low energy dissipation for a biosensing platform, the system's power consumption is orders of magnitude lower than any reported work. The summary of requirements for wearable EEG systems using active electrodes in [13] provides a set of specifications that should be met to perform reliable readouts with a wireless solution and it will be used as a reference for this paper. Similarly, [14] shows the performance requirements for neuro-recording amplifiers in implantable devices, which -in terms of power-are still orders of magnitude higher than the proposed solution.…”

Section: E Comparison With State Of the Artmentioning

confidence: 99%

See 1 more Smart Citation

11nW Signal Acquisition Platform for Remote Biosensing

Gancedo

Akgun

Serdijn

2019

2019 IEEE Biomedical Circuits and Systems Conference (BioCAS)

View full text Add to dashboard Cite

This paper presents the design of an extremely lowenergy biosensing platform that utilizes voltage to time conversion and time-mode signal processing to sense and accommodate electrophysiological biosignals that will be later sent remotely using a simple and low power communication scheme. The electrode input is fed to a chain of monostable multivibrators used as analog-to-time converters, which create time pulses whose widths are proportional to the input signal. These pulses are transmitted to an external receiver by means of singlepulse harmonic modulation as the communication scheme, at a carrier frequency of 10 MHz. The platform is designed to be implemented in a standard 0.18 µm IC process with an energy dissipation per sample per channel of 42.72 pJ, including communication, operating from a supply voltage of 0.6V with an input referred noise of 12.3µVrms. The resulting SNR for OSR=256 is 35.19 dB, and the system's power consumption at a sampling and communication rate of 256 Hz is 10.94 nW.

show abstract

Section: E Comparison With State Of the Artmentioning

confidence: 99%

“…OF WEARABLE EEG APPLICATIONS[13], NEURO-RECORDING AMPLIFIERS[14],AND THE PERFORMANCE OF THIS WORK Neuro-recording amplifiers per conversion and transmission, with 12.3µV rms input referred noise over a 1.48 kHz band. While operating at a sampling and communication rate of 256 Hz, the power consumption is 10.94 nW.…”

mentioning

confidence: 99%

11nW Signal Acquisition Platform for Remote Biosensing

Gancedo

Akgun

Serdijn

2019

2019 IEEE Biomedical Circuits and Systems Conference (BioCAS)

View full text Add to dashboard Cite

show abstract

“…However, the flaw is its high electrode-skin impedance. Typical dry-electrode impedance is in a range from a few hundreds of kiloohms to a few tens of megaohms [3], leading to a large signal attenuation and a significant increase in noise and offset [4].…”

Section: Introductionmentioning

confidence: 99%

Low Noise, High Input Impedance Digital-Analog Hybrid Offset Suppression Amplifier for Wearable Dry Electrode ECG Monitoring

Wang

Wei

et al. 2020

Electronics

View full text Add to dashboard Cite

The portable real-time electrocardiogram (ECG) is a convenient and promising electronic device for cardiovascular diseases patients. However, unlike wet gel electrodes in traditional clinical applications, dry electrodes are competent for comfortable long-time wearing and can prevent skin ulceration. Its ultra-high source impedance and electrode offset (EOS) make traditional chopper amplifiers with low input impedance and limited EOS range difficult to apply to this area. To overcome these challenges, this paper proposes a novel chopper amplifier topology. This architecture includes a gain control loop, a ripple reduction loop, and a DC-servo loop (DSL). The proposed sampling input stage and digital-analog hybrid DSL are employed to boost input impedance and extend the EOS handing range. Designed with a 0.18 µm 1P6M 1.8 V CMOS salicide process, the proposed chopper capacitively coupled instrumentation amplifier achieves an ultra-high input impedance of 120 GΩ (<0.05 Hz) or 2.1 GΩ (0.6~250 Hz), an EOS handing range of ±325 mV and a low noise of 1.9 μVrms at 0.6~250 Hz. It occupies an area of 0.36 mm2 and only consumes a quiescent current of 11 μA.

show abstract

“…The study of social interactions between individuals has prompted the coupling of multiple EEG/MEG systems to one another; the method is often called hyperscanning [14]. Developments in technology are now also allowing portable dry-electrode EEG [15,16,17,18] to be used in naturalistic environments. In all of these cases, it is critical to preserve the integrity and quality of the data despite the considerable increase in experimental complexity.…”

Section: Introduction: the Evolution Of Eeg/meg Studiesmentioning

confidence: 99%

A Review of Issues Related to Data Acquisition and Analysis in EEG/MEG Studies

2017

View full text Add to dashboard Cite

Electroencephalography (EEG) and magnetoencephalography (MEG) are non-invasive electrophysiological methods, which record electric potentials and magnetic fields due to electric currents in synchronously-active neurons. With MEG being more sensitive to neural activity from tangential currents and EEG being able to detect both radial and tangential sources, the two methods are complementary. Over the years, neurophysiological studies have changed considerably: high-density recordings are becoming de rigueur; there is interest in both spontaneous and evoked activity; and sophisticated artifact detection and removal methods are available. Improved head models for source estimation have also increased the precision of the current estimates, particularly for EEG and combined EEG/MEG. Because of their complementarity, more investigators are beginning to perform simultaneous EEG/MEG studies to gain more complete information about neural activity. Given the increase in methodological complexity in EEG/MEG, it is important to gather data that are of high quality and that are as artifact free as possible. Here, we discuss some issues in data acquisition and analysis of EEG and MEG data. Practical considerations for different types of EEG and MEG studies are also discussed.

show abstract

Active Electrodes for Wearable EEG Acquisition: Review and Electronics Design Methodology

Cited by 139 publications

References 65 publications

11nW Signal Acquisition Platform for Remote Biosensing

11nW Signal Acquisition Platform for Remote Biosensing

Low Noise, High Input Impedance Digital-Analog Hybrid Offset Suppression Amplifier for Wearable Dry Electrode ECG Monitoring

A Review of Issues Related to Data Acquisition and Analysis in EEG/MEG Studies

Contact Info

Product

Resources

About