CMOS integrated avalanche photodiodes and frequency-mixing optical sensor front end for portable NIR spectroscopy instruments

Yun, Ruida; Joyner, Valencia M.

doi:10.1109/iembs.2011.6089884

Cited by 4 publications

(7 citation statements)

References 9 publications

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“…Advanced silicon micro-fabrication processing, such as Complementary Metal Oxide Semiconductor (CMOS) technology, allows monolithic integration of photodetectors and signal conditioning circuitry on a single chip. Thus, for miniaturized design of a microspectrophotometer, the use of CMOS will be beneficial for application in non-invasive glucose monitoring [147][148][149][150]. It is inferred from the above analysis that accurate and reliable NIRS based non-invasive glucose measurement requires significant improvement to replace the conventional blood glucose measurement methods.…”

Section: Limitation and Challenges Of Nirs Based Glucose Monitoringmentioning

confidence: 99%

Prospects and limitations of non-invasive blood glucose monitoring using near-infrared spectroscopy

Yadav

Rani

Singh

et al. 2015

Biomedical Signal Processing and Control

297

144

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Section: Limitation and Challenges Of Nirs Based Glucose Monitoringmentioning

confidence: 99%

Prospects and limitations of non-invasive blood glucose monitoring using near-infrared spectroscopy

Yadav

Rani

Singh

et al. 2015

Biomedical Signal Processing and Control

297

144

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“…The wideband TIA architecture is adapated from [30]- [32] with a single fixed resistor feedback as opposed to a T-Feedback structure. In [31], the T-feedback structure was implemented to enable frequency mixing using a variable resistance in feedback.…”

Section: A Low Noise Front-end Designmentioning

confidence: 99%

A CMOS Sensor for Measurement of Cerebral Optical Coefficients Using Non-Invasive Frequency Domain Near Infrared Spectroscopy

Koomson

2013

IEEE Sensors J.

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A heterodyned architecture is integrated with a 180 nm CMOS chip for use in portable frequency domain near infrared spectroscopy (fdNIRS) tools for real time monitoring of tissue oxygenation in the brain. The design and performance measurement results of this chip are summarized in this paper to demonstrate its applicability in multi-distance fdNIRS to measure the absorption and scattering coefficients of tissue. The 2.25 mm 2 chip is integrated with four sensor channels, which have a high frequency low noise front end and information processing circuitry to interface with an avalanche photodiode to detect the high speed weak light signal. The four-channel sensor draws 40 mA of current from a 1.8 V power supply and uses an offchip counter implemented on an FPGA to quantify the amplitude and phase information required for tissue characterization with < 6.5% and < 2.5% linearity error, respectively. An experiment using the multi-distance measurement is used to measure the optical properties of a homogeneous tissue phantom using the CMOS integrated instrument.Index Terms-Frequency domain near infrared spectroscopy, CMOS, transimpedance amplifier, amplitude and phase detection, amplifier noise, optical sensor.

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“…Alternative approaches based on CMOS-integrated solutions have also been proposed. In 2011, Yun et al [ 59 ] proposed the designs of CMOS-integrated APDs and frequency-mixing transimpedance amplifiers (TIA, converting current from APD to output voltage). The TIA can realize simultaneous down-conversion and amplification of the photodiode current.…”

Section: State-of-the-art Fd-nirs Technologiesmentioning

confidence: 99%

“…The TIA can realize simultaneous down-conversion and amplification of the photodiode current. In 2013, Sthalekar and Koomson [ 60 ] utilized the TIA architecture from [ 59 ] and proposed a 4-channel sensor design on a 2.25 mm 2 chip for FD-NIRS measurements. The 100 MHz current signals from the photodetector were converted to a high-frequency voltage with the TIA.…”

Section: State-of-the-art Fd-nirs Technologiesmentioning

confidence: 99%

See 1 more Smart Citation

Review of recent advances in frequency-domain near-infrared spectroscopy technologies [Invited]

Zhou¹,

Xia

Uchitel

et al. 2023

Biomed. Opt. Express

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Over the past several decades, near-infrared spectroscopy (NIRS) has become a popular research and clinical tool for non-invasively measuring the oxygenation of biological tissues, with particular emphasis on applications to the human brain. In most cases, NIRS studies are performed using continuous-wave NIRS (CW-NIRS), which can only provide information on relative changes in chromophore concentrations, such as oxygenated and deoxygenated hemoglobin, as well as estimates of tissue oxygen saturation. Another type of NIRS known as frequency-domain NIRS (FD-NIRS) has significant advantages: it can directly measure optical pathlength and thus quantify the scattering and absorption coefficients of sampled tissues and provide direct measurements of absolute chromophore concentrations. This review describes the current status of FD-NIRS technologies, their performance, their advantages, and their limitations as compared to other NIRS methods. Significant landmarks of technological progress include the development of both benchtop and portable/wearable FD-NIRS technologies, sensitive front-end photonic components, and high-frequency phase measurements. Clinical applications of FD-NIRS technologies are discussed to provide context on current applications and needed areas of improvement. The review concludes by providing a roadmap toward the next generation of fully wearable, low-cost FD-NIRS systems.

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CMOS integrated avalanche photodiodes and frequency-mixing optical sensor front end for portable NIR spectroscopy instruments

Cited by 4 publications

References 9 publications

Prospects and limitations of non-invasive blood glucose monitoring using near-infrared spectroscopy

Prospects and limitations of non-invasive blood glucose monitoring using near-infrared spectroscopy

A CMOS Sensor for Measurement of Cerebral Optical Coefficients Using Non-Invasive Frequency Domain Near Infrared Spectroscopy

Review of recent advances in frequency-domain near-infrared spectroscopy technologies [Invited]

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