Enrollment Date : 2014
Anticipated Graduation Date:2019
Type of Candidate:Ph.D. Candidate
Advisors:Woogeun Rhee
Department:Institute of Microelectronics,Tsinghua University
Research Area:
[1] Haixin Song,Dang Liu,Yining Zhang,Woogeun Rhee,Zhihua Wang, A 6.5–8.1-GHz Communication/Ranging VWB Transceiver for Secure Wireless Connectivity With Enhanced Bandwidth Efficiency and ΔΣ Energy Detection, IEEE Journal of Solid-State Circuits, Vol.55, No.2, pp. 219 - 232, 2020.
[2] Haixin Song,Dang Liu,Yining Zhang,Woogeun Rhee,Zhihua Wang, A 6.5-8.1-GHz Communication/Ranging VWB Transceiver for Secure Wireless Connectivity With Enhanced Bandwidth Efficiency and ΔΣ Energy Detection, IEEE Journal of Solid-State Circuits, Vol.PP, No.99, pp. 1 - 14, 2019.
[3] Xiaohua Huang,Dang Liu,Woogeun Rhee,Zhihua Wang, A 1-GHz 1.6-mW Auto-Calibrated Bit Slicer for Energy/Envelope Detection Receivers, IEEE Transactions on Circuits and Systems II: Express Briefs, Vol.65, No.5, pp. 587 - 591, 2018.
[4] Dang Liu,Xiaohua Huang,Zhendong Ding,Haixin Song,Woogeun Rhee,Zhihua Wang, A 26.6mW 1Gb/s dual-antenna wideband receiver with auto beam steering for secure proximity communications, CICC 2018, 2018.
[5] Haixin Song,Dang Liu,Woogeun Rhee,Zhihua Wang, A 6-8GHZ 200MHz Bandwidth 9-Channel VWB Transceiver with 8 Frequency-Hopping Subbands, A-SSCC 2018, pp. 295 - 298, 2018.
[6] Dang Liu,Xuwen Ni,Ranran Zhou,Woogeun Rhee,Zhihua Wang, A 0.42-mW 1-Mb/s 3- to 4-GHz Transceiver in 0.18- μm CMOS With Flexible Efficiency, Bandwidth, and Distance Control for IoT Applications, IEEE Journal of Solid-State Circuits, Vol.52, No.6, pp. 1479 - 1494, 2017.
[7] Woogeun Rhee,Dang Liu,Yining Zhang,Zhihua Wang, Energy-efficient proprietary transceivers for IoT and smartphone-based WPAN, RFIT 2017, pp. 40 - 42, 2017.
[8] Xiaofeng Liu,Dang Liu,Woogeun Rhee,Zhihua Wang, A Multiphase Clock Generation for UWB Transceiver, Microelectronics & Computer, Vol.33, No.11, pp. 87-90+94, 2016.
[9] Shuli Geng,Dang Liu,Yanfeng Li,Huiying Zhuo,Woogeun Rhee,Zhihua Wang, A 13.3 mW 500 Mb/s IR-UWB Transceiver With Link Margin Enhancement Technique for Meter-Range Communications, IEEE Journal of Solid-State Circuits, Vol.50, No.3, pp. 669 - 678, 2015.
[10] Yu Li,Fei Chen,Dang Liu,Xiaoyong Li,Yang Li,Yudong Zhang,Zhicheng Wang,Woogeun Rhee,Zhihua Wang, A 1.6Mb/s 3.75–4.25GHz chirp-UWB transceiver with enhanced spectral efficiency in 0.18μm CMOS, RFIT 2014, pp. 1 – 3, 2014.
[11] Fei Chen,Yu Li,Dang Liu,Woogeun Rhee,Jongjin Kim,Dongwook Kim,Zhihua Wang, A 1mW 1Mb/s 7.75-to-8.25GHz chirp-UWB transceiver with low peak-power transmission and fast synchronization capability, ISSCC 2014, pp. 162 - 163, 2014.
[12] Shuli Geng,Dang Liu,Yanfeng Li,Huiying Zhuo,Woogeun Rhee,Zhihua Wang, A 13.3mW 500Mb/s IR-UWB Transceiver with Link-Margin Enhancement Technique for Meter-Range Communications, ISSCC 2014, pp. 160 - 161, 2014.
[13] Dang Liu,Shuli Geng,Woogeun Rhee,Zhihua Wang, A high efficiency robust IR-UWB receiver design for high data rate CM-range communications, ISCAS 2014, pp. 1901 - 1904, 2014.
[14] Hang Lv,Bo Zhou,Dang Liu,Woogeun Rhee,Yongming Li,Zhihua Wang, A 5.2–11.8MHz octa-phase relaxation oscillator for 8-PSK FM-UWB transceiver systems, VLSI-DAT 2013, pp. 1 - 4, 2013.
[15] Dang Liu,Fei Chen,Woogeun Rhee,Zhihua Wang, An FM-UWB transceiver with M-PSK subcarrier modulation and regenerative FM demodulation, MWSCAS 2013, pp. 936 – 939, 2013.