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ORCIDHao Gao 0001
Person information
- affiliation (PhD 2016): Eindhoven University of Technology, Department of Electrical Engineering, Mixed-Signal Microelectronics Group, The Netherlands
Other persons with the same name
- Hao Gao — disambiguation page
- Hao Gao 0002
![[0000-0001-6852-9435]](https://dblp.uni-trier.de./img/orcid-mark.12x12.png "0000-0001-6852-9435")
— University of Glasgow, School of Mathematics and Statistics, UK (and 1 more) - Hao Gao 0003 — Duke University Medical Center, Department of Radiation Oncology, Durham, NC, USA
- Hao Gao 0004 — Fudan University, Department of Communication Science and Engineering, Shanghai, China
- Hao Gao 0005 — Nanjing University of Posts and Telecommunications, China (and 1 more)
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2020 – today
- 2024
[j17]Zongming Duan, Yun Fang, Haoran Zhu, Bowen Wu, Yan Wang, Yuefei Dai, Hao Gao:
A S-band switchless bi-directional transceiver with a 52% fractional bandwidth in CMOS technology. Microelectron. J. 143: 106036 (2024)- [j16]Lin He, Hengzhuang Shi, Junhui Zhang, Mingxiang Wei, Ping Wang, Shunming Li, Hao Gao, Zhikuang Cai:
A CMOS Current Sensing Interface With Sub-pA DC Uncertainty. IEEE Trans. Circuits Syst. II Express Briefs 71(2): 508-512 (2024) - [c33]Dawei Tang, Xiaoyue Xia, Zheng Yan, Peigen Zhou, Zekun Li, Chun Yang, Rui Zhang, Zhe Chen, Jixin Chen, Hao Gao, Wei Hong:
24.1 A 90-to-180GHz APD-Integrated Transmitter Achieving 18dBm Psat in 28nm CMOS. ISSCC 2024: 411-413 - 2023
- [j15]Kuangyuan Ying, Hao Gao:
A 25% Tuning Range 7.5-9.4 GHz Oscillator With 194 FoMT and 400 kHz 1/f₃ Corner in 40nm CMOS Technology. IEEE Access 11: 6351-6356 (2023) - [j14]Jiayang Yu, Jixin Chen, Peigen Zhou, Huanbo Li, Zuojun Wang, Zekun Li, Zhe Chen, Pinpin Yan, Debin Hou, Hao Gao, Wei Hong:
A 211-to-263-GHz Dual-LC-Tank-Based Broadband Power Amplifier With 14.7-dBm PSAT and 16.4-dB Peak Gain in 130-nm SiGe BiCMOS. IEEE J. Solid State Circuits 58(2): 332-344 (2023) - [j13]Zongming Duan, Bowen Wu, Yan Wang, Yun Fang, Yongjie Li, Yanhui Wu, Tao Zhang, Chuanming Zhu, Yuefei Dai, Lei Sang, Hao Gao:
A 76-81 GHz 2×8 MIMO Radar Transceiver With Broadband Fast Chirp Generation and 16-Antenna-in-Package Virtual Array. IEEE J. Solid State Circuits 58(11): 3103-3112 (2023) - [c32]Haoqi Qin, Junjie Gu, Hao Xu, Weitian Liu, Kefeng Han, Rui Yin, Zongming Duan, Hao Gao, Na Yan:
A 26-30GHz Digitally-Controlled Variable Gain Power Amplifier with Phase Compensation and Third Order Nonlinearity Cancellation Technique. A-SSCC 2023: 1-3 - [c31]Yun Fang, Hao Gao:
Millimeter-Wave Dual-Frequency Transformer-based Rectifier. ICICDT 2023: 41-43 - [c30]Kai Tang, Ting Guo, Xiaolin Sun, Chun Zhao, Hao Gao, Yuanjin Zheng:
Low-power MEMS-based CMOS Transceivers. ICICDT 2023: 44-47 - 2022
- [j12]Peigen Zhou, Jixin Chen, Pinpin Yan, Jiayang Yu, Debin Hou, Hao Gao, Wei Hong:
An E-Band SiGe High Efficiency, High Harmonic Suppression Amplifier Multiplier Chain With Wide Temperature Operating Range. IEEE Trans. Circuits Syst. I Regul. Pap. 69(3): 1041-1050 (2022) - [j11]Yongjie Li, Zongming Duan, Yun Fang, Xiao Li, Biao Deng, Yuefei Dai, Liguo Sun, Hao Gao:
A 32-40 GHz 7-bit Bi-Directional Phase Shifter With 0.36 dB/1.6° RMS Magnitude/Phase Errors for Phased Array Systems. IEEE Trans. Circuits Syst. I Regul. Pap. 69(10): 4000-4013 (2022) - [j10]Xu Cheng, Feng-Jun Chen, Liang Zhang, Hao Gao, Jiangan Han, Jing-Yu Han, Yang Yu, Xianjin Deng:
A Closed-Loop Reconfigurable Analog Baseband Circuitry With Open-Loop Tunable Notch Filters to Improve Receiver Tx Leakage and Close-in Blocker Tolerance. IEEE Trans. Circuits Syst. II Express Briefs 69(3): 839-843 (2022) - [c29]Hao Gao, Sina Mortezazadeh Mahani, David Seebacher, Matteo Bassi, Gernot Hueber:
A 24-30 GHz Broadband Doherty PA with a maximum 15.37 dBm Pavg and 14.6% PAEavg in 0.13 μm SiGe for 400 MHz BW 5G NR. ESSCIRC 2022: 337-340 - [c28]Sarthak Sharma, Hao Gao, Gernot Hueber, Andrea Mazzanti:
A Magnetically Coupled Dual-Core 154-GHz Class-F Oscillator with -177.1 FoM and -87 dBc/Hz PN at 1-MHz Offset in a 22-nm FDSOI with Third-Harmonic Extraction. VLSI Technology and Circuits 2022: 12-13 - 2021
- [j9]Peigen Zhou, Jixin Chen, Pinpin Yan, Jiayang Yu, Jiarui Hu, Haoyi Dong, Long Wang, Debin Hou, Hao Gao, Wei Hong:
A -28.5-dB EVM 64-QAM 45-GHz Transceiver for IEEE 802.11aj. IEEE J. Solid State Circuits 56(10): 3077-3093 (2021) - [j8]Yun Fang, Zhong Tang, Xiao-Peng Yu, Zhiwei Xu, Hao Gao:
Broadband linearity enhancement method for a 1.3 GHz-2.5 GHz digitally-assisted oscillator in a 55-nm CMOS technology. Microelectron. J. 113: 105103 (2021) - [j7]Yang Liu, Zhiqun Li, Hao Gao:
A 24 GHz PLL with low phase noise for 60 GHz Sliding-IF transceiver in a 65-nm CMOS. Microelectron. J. 113: 105106 (2021) - [c27]Hao Gao:
Silicon-based sub-THz PA for Wireless Communication. ICICDT 2021: 1-3 - [c26]Jiachen Shen, Yi Zhang, Liu Yang, Lin He, Yufeng Guo, Hao Gao:
Wideband Digitally Controlled True Time Delay for Beamforming in a 40 nm CMOS Technology. ISCAS 2021: 1-4 - [c25]Guanglai Wu, Yi Zhang, Lin He, Diyang Gao, Yang Liu, Yufeng Guo, Hao Gao:
A 77 GHz Power Amplifier Design with in-Phase Power Combing for 20 dBm Psat in a 40-nm CMOS Technology. ISCAS 2021: 1-4 - [c24]Zongming Duan, Bowen Wu, Chuanming Zhu, Yan Wang, Weiwei Jin, Ying Liu, Yanhui Wu, Tao Zhang, Ming Liu, Bingfei Dou, Bingbing Liao, Wei Lv, Dongfang Pan, Yongjie Li, Changwei Wang, Yuefei Dai, Pei Li, Hao Gao:
14.6 A 76-to-81GHz 2×8 FMCW MIMO Radar Transceiver with Fast Chirp Generation and Multi-Feed Antenna-in-Package Array. ISSCC 2021: 228-230
2010 – 2019
- 2019
- [c23]Carlos A. M. Costa Júnior, Chu Wang, Kuangyuan Ying, Zhe Chen, Miguel Dhaens, Hao Gao, Peter G. M. Baltus:
Fully Integrated Tunable Wideband True Time Delay for Wireless Sensor Networks. ISCAS 2019: 1-5 - 2018
- [j6]Hao Gao, Marion K. Matters-Kammerer, Peter G. M. Baltus:
A 60 GHz Low Power Self-mixing Receiver in 65-nm CMOS for a Radio-Triggered Battery-Less Monolithic Wireless Sensor. IEEE J. Emerg. Sel. Topics Circuits Syst. 8(2): 240-250 (2018) - [j5]Yi Zhang, Xiaopeng Li, Youtao Zhang, Qingguo Ye, Ying Zhang, Yufeng Guo, Hao Gao:
A 1.2 GSps, 8 bit RF DAC for multi-Nyquist applications in GaAs technology. IEICE Electron. Express 15(20): 20180773 (2018) - [c22]Kuangyuan Ying, Carlos A. M. Costa Júnior, Bindi Wang, Dusan M. Milosevic, Hao Gao, Peter G. M. Baltus:
A Reconfigurable Receiver with 38 dB Frequency-Independent Blocker Suppression and Enhanced in-B and Linearity and Power Efficiency. ESSCIRC 2018: 74-77 - [c21]Debashis Dhar, Paul T. M. van Zeijl, Dusan M. Milosevic, Hao Gao, Peter G. M. Baltus:
Analysis of the Effect of PFD Sampling on Charge-Pump PLL Stability. ISCAS 2018: 1-5 - [c20]Piyush Kaul, Hao Gao, Xin He, Peter G. M. Baltus:
An UWB, Low-Noise, Low-Power Quadrature VCO using Delay-Locked Loop in 40-nm CMOS for Image-Rejection Receivers. ISCAS 2018: 1-5 - [c19]Kuangyuan Ying, Hao Gao, Xiaowen Min, Dusan M. Milosevic, Peter G. M. Baltus:
A Wideband Envelope Detector with Low Ripple and High Detection Speed. ISCAS 2018: 1-5 - [c18]Zhe Chen, Hao Gao, Peter G. M. Baltus:
A Design Approach for SiGe Low-Noise Amplifiers Using Wideband Input Matching. NORCAS 2018: 1-4 - 2017
- [j4]Yang Liu, Zhiqun Li, Hao Gao, Qin Li, Zhigong Wang:
A novel complementary push-push frequency doubler with negative resistor conversion gain enhancement. IEICE Electron. Express 14(15): 20170674 (2017) - [j3]Kuangyuan Ying, Hao Gao, Dusan M. Milosevic, Peter G. M. Baltus:
A Nonlinear Transfer Function Based Receiver for Wideband Interference Suppression. J. Sensors 2017: 2405942:1-2405942:15 (2017) - [j2]Xiongchuan Huang, Xiaopeng Yu, Chao Wang, Hao Gao:
Circuits and Systems for Wireless Sensing. J. Sensors 2017: 4045780:1-4045780:2 (2017) - [c17]Debashis Dhar, Paul T. M. van Zeijl, Dusan M. Milosevic, Hao Gao, Peter G. M. Baltus:
Noise analysis of a BJT-based charge pump for low-noise PLL applications. ECCTD 2017: 1-4 - [c16]Jialue Wang, Yang Jiang, Johan Dijkhuis, Guido Dolmans, Hao Gao, Peter G. M. Baltus:
A 900 MHz RF energy harvesting system in 40 nm CMOS technology with efficiency peaking at 47% and higher than 30% over a 22dB wide input power range. ESSCIRC 2017: 299-302 - [c15]Debashis Dhar, Paul T. M. van Zeijl, Dusan M. Milosevic, Hao Gao, Arthur H. M. van Roermund:
Modeling and analysis of the effects of PLL phase noise on FMCW radar performance. ISCAS 2017: 1-4 - [c14]Bindi Wang, Hao Gao, Marion K. Matters-Kammerer, Peter G. M. Baltus:
Interpolation based wideband beamforming architecture. ISCAS 2017: 1-4 - 2016
- [j1]Pieter Harpe, Hao Gao, Rainier van Dommele, Eugenio Cantatore, Arthur H. M. van Roermund:
A 0.20 mm2 3 nW Signal Acquisition IC for Miniature Sensor Nodes in 65 nm CMOS. IEEE J. Solid State Circuits 51(1): 240-248 (2016) - [c13]Zhe Chen, Hao Gao, Domine M. W. Leenaerts, Dusan M. Milosevic, Peter G. M. Baltus:
A 16-43 GHz low-noise amplifer with 2.5-4.0 dB noise figure. A-SSCC 2016: 349-352 - [c12]Zhe Chen, Hao Gao, Rainier van Dommele, Dusan M. Milosevic, Peter G. M. Baltus:
Poster: Design consideration of 60 GHz low power low-noise amplifier in 65 nm CMOS. SCVT 2016: 1-4 - [c11]Bindi Wang, Hao Gao, Kuangyuan Ying, Marion K. Matters-Kammerer, Peter G. M. Baltus:
Poster: A 60 GHz phased array system evaluation based on a 5-bit phase shifter in CMOS technology. SCVT 2016: 1-4 - 2015
- [c10]Bindi Wang, Yao-Hong Liu, Pieter Harpe, Johan H. C. van den Heuvel, Bo Liu, Hao Gao, Robert Bogdan Staszewski:
A digital to time converter with fully digital calibration scheme for ultra-low power ADPLL in 40 nm CMOS. ISCAS 2015: 2289-2292 - [c9]Pieter Harpe, Hao Gao, Rainier van Dommele, Eugenio Cantatore, Arthur H. M. van Roermund:
21.2 A 3nW signal-acquisition IC integrating an amplifier with 2.1 NEF and a 1.5fJ/conv-step ADC. ISSCC 2015: 1-3 - 2014
- [c8]Hao Gao, Marion K. Matters-Kammerer, Pieter Harpe, Dusan M. Milosevic, Arthur H. M. van Roermund, Jean-Paul M. G. Linnartz, Peter G. M. Baltus:
A 60-GHz energy harvesting module with on-chip antenna and switch for co-integration with ULP radios in 65-nm CMOS with fully wireless mm-wave power transfer measurement. ISCAS 2014: 1640-1643 - [c7]Hao Gao, Marion K. Matters-Kammerer, Xia Li, Dusan M. Milosevic, Arthur H. M. van Roermund, Peter G. M. Baltus:
A 60-GHz injection locked oscillator for self-demodulation ultra-low power radio in 65-nm CMOS. SCVT 2014: 90-93 - 2013
- [c6]Hao Gao, Yan Wu, Marion K. Matters-Kammerer, Jean-Paul M. G. Linnartz, Arthur H. M. van Roermund, Peter G. M. Baltus:
System analysis and energy model for radio-triggered battery-less monolithic wireless sensor receiver. ISCAS 2013: 1572-1575 - [c5]Hao Gao, Ulf Johannsen, Marion K. Matters-Kammerer, Dusan M. Milosevic, Adrianus Bart Smolders, Arthur H. M. van Roermund, Peter G. M. Baltus:
A 60-GHz rectenna for monolithic wireless sensor tags. ISCAS 2013: 2796-2799 - [c4]Yan Wu, Jean-Paul M. G. Linnartz, Hao Gao, Marion K. Matters-Kammerer, Peter G. M. Baltus:
Modeling of RF energy scavenging for batteryless wireless sensors with low input power. PIMRC 2013: 527-531 - [c3]Hao Gao, Yan Wu, Marion K. Matters-Kammerer, Dusan M. Milosevic, Jean-Paul M. G. Linnartz, Peter G. M. Baltus:
System analysis and energy model of 60GHz radio-triggered wireless sensor receiver. SCVT 2013: 1-4 - [c2]Hao Gao, Marion K. Matters-Kammerer, Dusan M. Milosevic, Jean-Paul M. G. Linnartz, Peter G. M. Baltus:
A design of 2.4GHz rectifier in 65nm CMOS with 31% efficiency. SCVT 2013: 1-4 - 2011
- [c1]Yan Wu, Jean-Paul M. G. Linnartz, Hao Gao, Peter G. M. Baltus, Jan W. M. Bergmans:
System study of a 60 GHz wireless-powered monolithic sensor system. ICICS 2011: 1-5
Coauthor Index
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