A 36 μW 1.1 mm<sup>2</sup> Reconfigurable Analog Front-End for Cardiovascular and Respiratory Signals Recording

Xu, Jiawei; Konijnenburg, Mario; Ha, Hyunsoo; Wegberg, Roland van; Song, Shunfeng; Blanco-Almazan, Dolores; Hoof, Chris Van; Helleputte, Nick Van

doi:10.1109/tbcas.2018.2814699

Cited by 36 publications

(16 citation statements)

References 19 publications

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“…performance voltage acquisition front-ends for bioimpedance measurements have been reported [23], [24] but mainly for onechannel recording. Read-out chains for EIT that use current feedback IA for wideband, high CMRR have been also reported [25], [26].…”

Section: Cables Electrodesmentioning

confidence: 99%

A 122 fps, 1 MHz Bandwidth Multi-Frequency Wearable EIT Belt Featuring Novel Active Electrode Architecture for Neonatal Thorax Vital Sign Monitoring

Jiang

Bardill

et al. 2019

IEEE Trans. Biomed. Circuits Syst.

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A highly integrated, wearable electrical impedance tomography (EIT) belt for neonatal thorax vital multiple sign monitoring is presented. The belt has sixteen active electrodes. Each has an application specific integrated circuit (ASIC) connected to an electrode. The ASIC contains a fully differential current driver, a high-performance instrumentation amplifier (IA), a digital controller and multiplexors. The belt features a new active electrode architecture that allows programmable flexible electrode current drive and voltage sense patterns under simple digital control. It provides intimate connections to the electrodes for the current drive and to the IA for direct differential voltage measurement providing superior common-mode rejection ratio. The ASIC was designed in a CMOS 0.35-µm high-voltage technology. The high specification EIT belt has an image frame rate of 122 fps, a wide operating bandwidth of 1 MHz and multifrequency operation. It measures impedance with 98% accuracy and has less than 0.5 Ω and 1 o variation across all possible channels. The image results confirmed the advantage of the new active electrode architecture and the benefit of wideband, multifrequency EIT operation. The system successfully captured high quality lung respiration EIT images, breathing cycle and heart rate. It can also provide boundary shape information using an array of MEMS sensors interfaced to the ASICs.

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Section: Cables Electrodesmentioning

confidence: 99%

A 122 fps, 1 MHz Bandwidth Multi-Frequency Wearable EIT Belt Featuring Novel Active Electrode Architecture for Neonatal Thorax Vital Sign Monitoring

Jiang

Bardill

et al. 2019

IEEE Trans. Biomed. Circuits Syst.

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“…The H-bridge based current generator is often implemented using two independent carefully matched PMOS and NMOS current mirrors to source and sink the current across the load as shown in Fig. 2(a) with no common mode feedback; this approach suffers from ∆ current mismatch due to process variations [10]. Some electrical bioimpedance systems use micro-electrodes which have high contact impedance (up to a tens of kΩ); whereas the tissue impedance is only few hundred Ohms and decreases to a few mΩ at high frequency.…”

Section: Circuit Architecturementioning

confidence: 99%

“…The SPWM generator is fully digital where the LUT only contains 32 bits. On the other hand, SPWM provides significantly better SFDR than the square wave, which is also commonly used in EIS systems [10], [13].…”

Section: A Spectral Puritymentioning

confidence: 99%

A Power-Efficient Current Generator with Common Mode Signal Autozero Feedback for Bioimpedance Measurement Applications

Jiang

Langlois

et al. 2019

2019 IEEE International Symposium on Circuits and Systems (ISCAS)

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This paper describes the design of fully differential sine pulse-width-modulation (SPWM) wave current generator for bioimpedance measurement applications. The current generator has been designed in a 0.18-µm CMOS technology. Its analog front-end operates from ±1.65 V and has a current consumption of + + (× .) where is the output current and is the operating frequency. It can provide outputs from to of SPWM current up to 98 kHz with a maximum voltage compliance of ±1.25 V. Using linear current feedback, the current generator has a designed transconductance of /. Feedback also enables cancellation of common mode signals and a high output impedance. This work is funded by the European Commission under grant agreement no.

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“…A reconfigurable IA based on a current-balanced IA structure was published and showed various applications as shown in Figure 1b [8]. A reconfigurable IA based on a three OP amp IA structure was also published in [9]. In wearable and mobile environments, health monitoring devices use batteries.…”

Section: Introductionmentioning

confidence: 99%

Simultaneous Voltage and Current Measurement Instrumentation Amplifier for ECG and PPG Monitoring

Kim

2021

Electronics

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An instrumentation amplifier (IA) capable of sensing both voltage and current at the same time has been introduced and applied to electrocardiogram (ECG) and photoplethysmogram (PPG) measurements for cardiovascular health monitoring applications. The proposed IA can switch between the voltage and current sensing configurations in a time–division manner faster than the ECG and PPG bandwidths. The application-specific integrated circuit (ASIC) of the proposed circuit design was implemented using 180 nm CMOS fabrication technology. Input-referred voltage noise and current noise were measured as 3.9 µVrms and 172 pArms, respectively, and power consumption was measured as 34.9 µA. In the current sensing configuration, a current noise reduction technique is applied, which was confirmed to be a 25 times improvement over the previous version. Using a single IA, ECG and PPG can be monitored in the form of separated ECG and PPG signals. In addition, for the first time, a merged ECG/PPG signal is acquired, which has features of both ECG and PPG peaks.

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A 36 μW 1.1 mm² Reconfigurable Analog Front-End for Cardiovascular and Respiratory Signals Recording

Cited by 36 publications

References 19 publications

A 122 fps, 1 MHz Bandwidth Multi-Frequency Wearable EIT Belt Featuring Novel Active Electrode Architecture for Neonatal Thorax Vital Sign Monitoring

A 122 fps, 1 MHz Bandwidth Multi-Frequency Wearable EIT Belt Featuring Novel Active Electrode Architecture for Neonatal Thorax Vital Sign Monitoring

A Power-Efficient Current Generator with Common Mode Signal Autozero Feedback for Bioimpedance Measurement Applications

Simultaneous Voltage and Current Measurement Instrumentation Amplifier for ECG and PPG Monitoring

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A 36 μW 1.1 mm2 Reconfigurable Analog Front-End for Cardiovascular and Respiratory Signals Recording

Cited by 36 publications

References 19 publications

A 122 fps, 1 MHz Bandwidth Multi-Frequency Wearable EIT Belt Featuring Novel Active Electrode Architecture for Neonatal Thorax Vital Sign Monitoring

A 122 fps, 1 MHz Bandwidth Multi-Frequency Wearable EIT Belt Featuring Novel Active Electrode Architecture for Neonatal Thorax Vital Sign Monitoring

A Power-Efficient Current Generator with Common Mode Signal Autozero Feedback for Bioimpedance Measurement Applications

Simultaneous Voltage and Current Measurement Instrumentation Amplifier for ECG and PPG Monitoring

Contact Info

Product

Resources

About

A 36 μW 1.1 mm² Reconfigurable Analog Front-End for Cardiovascular and Respiratory Signals Recording