Your search keyword '"Liu, Yao-Hong"' showing total 8 results

1. An Injection-Locked Ring-Oscillator-Based Fractional-N Digital PLL Supporting BLE Frequency Modulation.

Author

He, Yuming, van den Heuvel, Johan, Mateman, Paul, Allebes, Erwin, Traferro, Stefano, Dijkhuis, Johan, Bunsen, Keigo, Vis, Peter, Breeschoten, Arjan, Liu, Yao-Hong, Matsumoto, Tomohiro, and Bachmann, Christian

Subjects

PHASE-locked loops, FREQUENCY shift keying, FREQUENCY synthesizers

Abstract

This article presents an injection-locked (IL) ring-oscillator-based fractional- ${N}$ digital phase locked loop (DPLL) supporting Bluetooth low energy (BLE) frequency modulation with an frequency-shift keying (FSK) error between 2.4% and 3.3%. As the fractional spur cannot be suppressed by IL-DPLL, this work proposes a random edge injection (REI) to reduce the spur. This technique also speeds up the convergence time of gain calibration of the digital-to-time converter (DTC). Furthermore, the proposed background calibration schemes allow the DPLL to achieve stable performance across all BLE channels, including both integer- ${N}$ and fractional- ${N}$ channels. This work was fabricated in the 40-nm CMOS technology occupying a 0.09-mm2 area. A fractional spur of −44 dBc and a reference spur of are achieved while consuming 2.76 mW when REI is activated. The background calibrations also ensure stable performance across BLE channels. [ABSTRACT FROM AUTHOR]

Published

2022

2. Design and Analysis of a DCO-Based Phase-Tracking RF Receiver for IoT Applications.

Author

Liu, Yao-Hong, Purushothaman, Vijaya Kumar, Bachmann, Christian, and Staszewski, Robert Bogdan

Subjects

ELECTRIC oscillators, INTERNET of things, ZIGBEE

Abstract

This paper presents an energy-/area-efficient digitally controlled oscillator (DCO)-based phase-tracking Receiver for Internet-of-Things (IoT) applications. The RX leverages the constant-envelope nature of frequency shift keying modulation adopted in many IoT protocols, e.g., IEEE802.15.4 and Bluetooth low energy (BLE), to enhance the energy efficiency and to reduce the chip area. The proposed RX, with the DCO acting as a local oscillator (LO) and binary frequency feedback, promotes low-power and low-voltage circuit design, while a data-aided carrier-frequency tracking ensures the received carrier stability without a power-/area-hungry phase-locked loop (PLL). The RX avoids a compromise between a power-hungry I/Q LO generation and the image rejection in traditional RXs. An equivalent mathematical model is further presented, which helps to analyze and optimize the frequency response of the proposed RX. Fabricated in 40-nm CMOS, the RX consumes 1.55 mW from a 0.85-V supply and has a −87-dBm sensitivity at 2 Mb/s, which leads to a 0.77-nJ/b energy efficiency and 178-dB RX sensitivity FoM. [ABSTRACT FROM AUTHOR]

Published

2019

3. A Direct Phase-Tracking Doppler Radar Using Wavelet Independent Component Analysis for Non-Contact Respiratory and Heart Rate Monitoring.

Author

Mercuri, Marco, Liu, Yao-Hong, Lorato, Ilde, Torfs, Tom, Wieringa, Fokko, Bourdoux, Andre, and Van Hoof, Chris

Abstract

A continuous wave Doppler radar, operating as a phase-locked-loop in phase demodulator configuration, is proposed and in vivo demonstrated for noncontact vital signs monitoring. The radar architecture exhibits a unique precision in tracking the phase modulation caused by human cardiopulmonary activity from which heartbeat and respiration can simultaneously be extracted. The single mixer architecture is immune to the null point and does not require small-angle approximation conditions, which distinguishes it from pre-existing other approaches. This enables the proposed radar to behave highly linear, with very precise detection of phase modulations induced by any kind of movement, independently from amplitude and speed. After simulations and technical tests to validate functionality and safety of the proposed architecture, a practical setup was demonstrated on human volunteers. Wavelet independent component analysis was applied to successfully retrieve respiratory and heart rate information from the radar baseband signal. [ABSTRACT FROM AUTHOR]

Published

2018

4. Frequency-Tracking CW Doppler Radar Solving Small-Angle Approximation and Null Point Issues in Non-Contact Vital Signs Monitoring.

Author

Mercuri, Marco, Liu, Yao-Hong, Lorato, Ilde, Torfs, Tom, Bourdoux, Andre, and Van Hoof, Chris

Abstract

A Doppler radar operating as a Phase-Locked-Loop (PLL) in frequency demodulator configuration is presented and discussed. The proposed radar presents a unique architecture, using a single channel mixer, and allows to detect contactless vital signs parameters while solving the null point issue and without requiring the small angle approximation condition. Spectral analysis, simulations, and experimental results are presented and detailed to demonstrate the feasibility and the operational principle of the proposed radar architecture. [ABSTRACT FROM PUBLISHER]

Published

2017

5. An Ultra-Low Power 1.7-2.7 GHz Fractional-N Sub-Sampling Digital Frequency Synthesizer and Modulator for IoT Applications in 40 nm CMOS.

Author

Liu, Yao-Hong, Van Den Heuvel, Johan, Kuramochi, Takashi, Busze, Benjamin, Mateman, Paul, Chillara, Vamshi Krishna, Wang, Bindi, Staszewski, Robert Bogdan, and Philips, Kathleen

Subjects

*INTERNET of things, *FREQUENCY synthesizers

Abstract

This paper introduces an ultra-low power 1.7-2.7-GHz fractional-N sub-sampling digital PLL (SS-DPLL) for Internet-of-Things (IoT) applications targeting compliance with Bluetooth Low Energy (BLE) and IEEE802.15.4 standards. A snapshot time-to-digital converter (TDC) acts as a digital sub-sampler featuring an increased out-of-range gain and without any assistance from the traditional counting of DCO edges, thus further reducing power consumption. With a proposed DCO-divider phase rotation in the feedback path, the impact of the digital-to-time converter’s (DTC’s) non-linearity on the PLL is reduced and improves fractional spurs by at least 8 dB across BLE channels. Moreover, a “variable-preconditioned LMS” calibration algorithm is introduced to dynamically correct the DTC gain error with fractional frequency control word (FCW) down to 1/16384. Fabricated in 40 nm CMOS, the SS-DPLL achieves phase noise performance of −109 dBc/Hz at 1 MHz offset, while consuming a record-low power of 1.19 mW. [ABSTRACT FROM AUTHOR]

Published

2017

6. A fully integrated 1.7–2.5GHz 1mW fractional-N PLL for WBAN and WSN applications.

Author

Vidojkovic, Maja, Liu, Yao-Hong, Huang, Xiongchuan, Imamura, Koji, Dolmans, Guido, and de Groot, Harmke

Abstract

This paper presents a wide-range low-power fully integrated fractional-N PLL. The PLL consumes 1.13mW to 1mW at 1.2V supply voltage, in a wide frequency range from 1.7GHz to 2.5GHz. It achieves up to −115 dBc/Hz phase noise at 1MHz offset and up to 2.5 degrees RMS phase error. The settling time is 40µs. The PLL is implemented in 90nm CMOS. The PLL can be used for low power wireless body area network (WBAN) and wireless sensor network (WSN) applications at 433MHz, 900MHz and 2.4 GHz. [ABSTRACT FROM PUBLISHER]

Published

2012

7. An energy-efficient polar transmitter for IEEE 802.15.6 body area networks: system requirements and circuit designs.

Author

Liu, Yao-Hong, Huang, Xiongchuan, Vidojkovic, Maja, Dolmans, Guido, and de Groot, Harmke

Subjects

*RADIO transmitter-receivers, *RADIO frequency modulation, *ELECTRONIC amplifiers, *IEEE 802.11 (Standard), *WIRELESS communications

Abstract

This article discusses the radio system requirements and design trade-offs of a low-power 2.3/2.4 GHz IEEE 802.15.6-narrowband transmitter for body area network applications. The IEEE 802.15.6 narrowband PHY adopts nonconstant envelope DPSK modulations. Transmitter architecture selection is a major challenge because it needs to provide both amplitude and phase modulation, with good efficiency and strict requirements on modulation accuracy and linearity for non-constant envelope modulations. A PLL-based polar transmitter with a Sigma-Delta digitally controlled power amplifier (SD-DPA) is employed for its excellent energy efficiency. Finally, this article discusses the circuit design considerations and implementation results. With balance between analog and digital implementation, and careful planning of the radio system, the polar transmitter presented in this article can meet all of the specifications defined in IEEE 802.15.6 with abundant margin, while having extremely low power consumption of 5.4 mW and excellent energy efficiency of 5.4 nJ/bit. [ABSTRACT FROM PUBLISHER]

Published

2012

8. A 2.7nJ/b multi-standard 2.3/2.4GHz polar transmitter for wireless sensor networks.

Author

Liu, Yao-Hong, Huang, Xiongchuan, Vidojkovic, Maja, Imamura, Koji, Harpe, Pieter, Dolmans, Guido, and De Groot, Harmke

Abstract

This paper presents an ultra-low-power (ULP) 2.3/2.4GHz multi-standard transmitter (TX) for wireless sensor networks and wireless body area networks. Several 2.3/2.4GHz wireless standards have been proposed for such applications, including IEEE802.15.6 (BAN) for body area networks, IEEE802.15.4 (Zigbee) and Bluetooth Low Energy (BLE) for sensor networks and IEEE802.15.4g (SUN) for smart buildings. Recent standard compliant short-range TXs [1–6] typically consume DC power in the range of 20 to 50mW. This is rather high for autonomous systems with limited battery energy. Implemented in a 90nm CMOS technology, the presented TX saves at least 75% of power consumption by replacing several power-hungry analog blocks with the digitally-assisted circuits. This TX is compliant with all 4 of these standards, while dissipating only 4.5mA from a 1.2V supply. [ABSTRACT FROM PUBLISHER]

Published

2012