William Wei-Ting Kuo scite author profile

William Wei-Ting Kuo

4Publications

28Citation Statements Received

62Citation Statements Given

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Affiliations

California Institute of Technology

Publications

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A 60-Gb/s PAM4 Wireline Receiver With 2-Tap Direct Decision Feedback Equalization Employing Track-and-Regenerate Slicers in 28-nm CMOS

Chen

Kuo

Emami

2021

IEEE J. Solid-State Circuits

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This article describes a 4-level pulse amplitude modulation (PAM4) receiver incorporating continuous time linear equalizers (CTLEs) and a 2-tap direct decision feedback equalizer (DFE) for applications in wireline communication. A CMOS track-and-regenerate slicer is proposed and employed in the PAM4 receiver. The proposed slicer is designed for the purposes of improving the clock-to-Q delay as well as the output signal swing. A direct DFE in a PAM4 receiver is made possible with the proposed slicer by having rail-to-rail digital feedback signals available with reduced delay, and accordingly relaxing the settling time constraint of the summer. With the 2-tap direct DFE enabled by the proposed slicer, loop-unrolling and inductor-based bandwidth enhancement techniques, which can be area/power intensive, are not necessary at high data rates. The PAM4 receiver fabricated in 28-nm CMOS technology achieves bit-error-rate (BER) better than 1E-12, and energy efficiency of 1.1 pJ/b at 60 Gb/s, measured over a channel with 8.2-dB loss at Nyquist.

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A Biofuel-Cell-Based Energy Harvester With 86% Peak Efficiency and 0.25-V Minimum Input Voltage Using Source-Adaptive MPPT

Talkhooncheh

You

Agarwal

et al. 2021

IEEE J. Solid-State Circuits

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This article presents an efficient cold-starting energy harvester system, fabricated in 65-nm CMOS. The proposed harvester uses no external electrical components and is compatible with biofuel-cell (BFC) voltage and power ranges. A power-efficient system architecture is proposed to keep the internal circuitry operating at 0.4 V while regulating the output voltage at 1 V using switched-capacitor dc-dc converters and a hysteretic controller. A startup enhancement block is presented to facilitate cold startup with any arbitrary input voltage. A realtime on-chip 2-D maximum power point tracking with source degradation tracing is also implemented to maintain power efficiency maximized over time. The system performs cold startup with a minimum input voltage of 0.39 V and continues its operation if the input voltage degrades to as low as 0.25 V. Peak power efficiency of 86% is achieved at 0.39 V of input voltage and 1.34 µW of output power with 220 nW of average power consumption of the chip. The end-to-end power efficiency is kept above 70% for a wide range of loading powers from 1 to 12 µW. The chip is integrated with a pair of lactate BFC electrodes with 2 mm of diameter on a prototype-printed circuit board (PCB). Integrated operation of the chip with the electrodes and a lactate solution is demonstrated.Index Terms-Biofuel-cell (BFC), CMOS, cold startup, dc-dc voltage converter, energy harvester, health monitoring, power management, source-adaptive maximum power point tracking (MPPT), wearable sensor. I. INTRODUCTIONR ECENT advances in low-power electronics have paved the way for a wide range of wearable and implantable biomedical devices for health monitoring and fitness applications. Integration of such millimeter-scale devices on biocompatible platforms shows great potentials for real-time biochemical sensing [1]- [6]. Many personalized monitoring biodevices are designed to perform multiple tasks, such as on-demand wake-up, multiplexed sensing, data processing, and wireless data transmission. These power-demanding operations are performed continuously or periodically over long Manuscript

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A Fully-Integrated Biofuel-Cell-Based Energy Harvester with 86% Peak Efficiency and 0.25V Minimum Input Voltage Using Source-Adaptive MPPT

Talkhooncheh

You

Agarwal

et al. 2020

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A 60-Gb/s PAM4 Wireline Receiver with 2-Tap Direct Decision Feedback Equalization Employing Track-and-Regenerate Slicers in 28-nm CMOS

Chen

Kuo

Emami

2020

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