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基本信息

姓名 职位 钱慧珍 教授/博士生导师

博士学科:微电子学与固体电子学

硕士学科:微电子学与固体电子学、集成电路工程

工作单位:微电子学院

联系方式

通信地址:西安电子科技大学微电子学院

电子邮箱:qianhuizhen@xidian.edu.cn

办公电话:

办公地点:西安电子科技大学南校区

个人简介

钱慧珍,西安电子科技大学微电子学院教授、博导,国家级青年人才。任IEEE MTT学会微波/毫米波集成电路技术委员会成员,IEEE高级会员,中国电子学会高级会员。本科、硕士、博士毕业于电子科技大学。发表论文80余篇,其中集成电路旗舰期刊JSSC12篇,集成电路“奥林匹克会议”IEEE ISSCC 4篇,IEEE汇刊论文JSSC,TMTT,TCAS-I共21篇,旗舰国际会议IEEE ISSCC、CICC、RFIC共18篇。授权发明专利34件,其中美国专利9件。获国家优秀青年基金,中国首位IEEE MTT学会杰出博士生奖;中国半导体十大进展候选两项;最佳论文奖4次。长期研究微波/毫米波/太赫兹集成电路,数字密集型射频集成电路,片上智能感知相控阵无线传输系统,可重构无源电路等。

长期招收本科生、硕士生、博士生,欢迎对集成电路设计感兴趣的同学加入!

研究方向

微波/毫米波/太赫兹集成电路,数字密集型射频集成电路,片上智能感知相控阵无线传输系统,可重构无源电路等。

科研项目

主持自然科学基金,教育部联合基金青年人才项目,国家基础重点项目课题等科研项目,主研国家重点研发计划重点专项、国家自然科学基金国际合作项目、自然科学基金重点项目、华为合作项目等十多个科研项目。设计多款高性能数字相控阵发射机、数字功率放大器、毫米波频率源、相控阵接收机等芯片。

教书育人获奖

指导学生获2021年IEEE固态电路学会博士生最高荣誉Predoctoral Achievement Award。

指导学生获得2020年IEEE微波理论与技术学会授予硕士/本科生最高荣誉IEEE MTT-S Undergraduate Scholarship Award(该奖全球每年不到10人)。

指导学生获2021年度“成电杰出学生”(研究生最高荣誉,全校每年仅10名)。

指导学生获2022年中国电子协会集成电路奖学金一等奖。

指导学生获2021年国际“互联网+”大学生创新创业大赛银奖。

指导学生获2019年IEEE International Microwave Symposium最佳学生设计竞赛奖。

获2021年四川省教学成果一等奖、二等奖。

学术兼职

兼任IEEE MTT-Society微波/毫米波集成电路技术委员会,IEEE高级会员,中国电子学会高级会员,IEEE JSSC、TMTT、IEEE TCAS-I、IEEE MWCL、IEEE TVLSI等期刊审稿人,兼任IEEE国际无线会议(IWS)、IEEE ICICM等国际会议技术委员会委员、分会主席等。

代表性论文

Journal Paper

J1 H. Tang,H. Qian, et al, “A self-calibration SCPA with storage capacitor array supporting 64-/256-/1024-QAM,”IEEE J. Solid-State Circuits (JSSC), vol. 58, no. 5, pp. 1241–1255, May 2023.

J2 Z. Deng, C. Han, Y. Li,H. Qian, et al, “A 23–40 GHz phased-array receiver using 14-bit phase-gain manager and wideband noise-cancelling LNA,”IEEE J. Solid-State Circuits (JSSC), vol. 58, no. 3, pp. 647–661, Mar. 2023.

J3 B. Yang,H. Qian, et al, “Millimeter-wave quadrature mixed-mode transmitter with distributed parasitic canceling and LO leakage self-suppression,”IEEE J. Solid-State Circuits (JSSC), vol. 58, no. 3, pp. 691–704, Mar. 2023.

J4 B. Yang,H. Qian, et al, “A CMOS wideband watt-level 4096-QAM digital power amplifier using reconfigurable power combining transformer,”IEEE J. Solid-State Circuits (JSSC), vol. 58, no. 2, pp. 357–370, Feb. 2023.

J5 Z. Deng,H. Qian, et al, “A reflectionless receiver with absorptive IF amplifier and dual-path noise-cancelling LNA,”IEEE J. Solid-State Circuits (JSSC), vol. 57, no. 8, pp. 2309–2319, Aug. 2022.

J6 B. Yang,H. Qian, et al, “Quadrature switched/floated capacitor power amplifier with reconfigurable self-coupling canceling transformer for deep back-off efficiency enhancement,”IEEE J. Solid-State Circuits (JSSC), vol. 56, no. 12, pp. 3715–3727, Dec. 2021.

J7 Y. Shu,H. Qian, et al, “A low phase noise and high FoM distributed-swing-boosting multi-core oscillator using harmonic-impedance-expanding technique,”IEEE J. Solid-State Circuits (JSSC), vol. 56, no. 12, pp. 3728–3740, Dec. 2021.

J8H. Qian, et al, “A 4-element digital modulated polar phased-array transmitter with phase modulation phase-shifting,”IEEE J. Solid-State Circuits (JSSC), vol. 56, no. 11, 3331–3347, Nov. 2021.

J9 Z. Deng, J. Zhou,H. Qian, et al, “A 22.9-38.2-GHz dual-path noise-canceling LNA with 2.65-4.62-dB NF in 28-nm CMOS,”IEEE J. Solid-State Circuits (JSSC), vol. 56, no. 11, pp. 3348–3359, Nov. 2021.

J10 Y. Shu,H. Qian, et al, “A 2-D mode-switching quad-core oscillator using E-M mixed-coupling resonance boosting,”IEEE J. Solid-State Circuits(JSSC), vol. 56, no. 6, pp. 1711–1721, Jun. 2021.

J11H. Qian, et al, “A quadrature digital power amplifier with hybrid Doherty and impedance boosting for complex domain power back-off efficiency enhancement,”IEEE J. Solid-State Circuits(JSSC), vol. 56, no. 5, 1487–1501, May 2021.

J12 W. Chen, Z. Deng, Y. Shu,H. Qian, et al, “Low NF and high P1dB wideband quasi-circulator with unequal power split and reconfigurable inter-stage matching,”IEEE Trans. Microw. Theory Tech., vol. 69, no. 4, pp. 2241–2252, Apr. 2021.

J13 D. Tang, C. Han, Z. Deng,H. Qian, et al, “Substrate integrated defected ground structure for single- and dual-band bandpass filters with wide stopband and low radiation loss,”IEEE Trans. Microw. Theory Tech., vol. 69, no. 1, pp. 659–670, Jan. 2021.

J14 Y. Shu,H. Qian, et al, “A cascaded mode-switching sub-sampling PLL with quadrature dual-mode voltage waveform-shaping oscillator,”IEEE Trans. Circuits and Systems—I: Regular Papers, vol. 68, no. 6, pp. 2341–2353, Jun. 2021.

J15 J. Zhou,H. Qian, et al, “High-resolution wideband vector-sum digital phase shifter with on-chip phase linearity enhancement technology,”IEEE Trans. Circuits and Systems—I: Regular Papers, vol. 68, no. 6, pp. 2457–2469, Jun. 2021.

J16 T. Wang,H. Qian, et al, “1.2–2.8-GHz 32.4-dBm digital power amplifier with balance-compensated matching network,”IEEE Microw. Wireless Compon. Lett., vol. 31, no. 1, pp. 41–44, Jan. 2021.

J17H. Qian, et al, “A 20−32GHz quadrature digital transmitter using synthesized impedance variation compensation,”IEEE J. Solid-State Circuits(JSSC), vol. 55, no. 5, pp.1297–1309, May 2020.

J18 X. Luo,H. Qian, et al, “Empowering multi-function: digital power amplifier, the last RF frontier of the analog and the digital kingdoms,”IEEE Microw. Magazine, vol. 21, no. 12, pp. 47–67, Dec. 2020. (Invited paper)

J19 Z. Deng,H. Qian, et al, “Tunable quasi-circulator based on a compact fully-reconfigurable 180° hybrid for full-duplex transceivers,”IEEE Trans. Circuits and Systems—I: Regular Papers, vol. 66, no. 8, pp. 2949–2962, Aug. 2019.

J20H. Qian, et al, “High resolution wideband phase shifter with current limited vector-sum”,IEEE Trans. Circuits and Systems—I: Regular Papers, vol. 66, no. 2, pp. 820–833, Feb. 2019.

J21 Y. Shu,H. Qian, et al, “A 169.6 GHz low phase noise and wideband hybrid mode-switching push-push oscillator,”IEEE Trans. Microw. Theory Tech., vol. 67, no. 7, pp. 2769–2781, Jul. 2019.

J22H. Qian, et al, “Wideband digital power amplifiers with efficiency improvement using 40-nm LP CMOS technology,”IEEE Trans. Microw. Theory Tech., vol. 64, no. 3, pp. 675–687, Mar. 2016.

Conference Paper

C1 B. Yang, Z. Deng,H. Qian, et al, “71–89GHz 12Gb/s double-edge-triggered quadrature RFDAC with LO leakage suppression achieving 20.5dBm peak output power and 20.4% system efficiency,” inIEEE ISSCC, San Franscisco, CA, USA, Feb. 2023.

C2 Z. Deng,H. Qian, et al, “A 3.8-dB NF, 23-40GHz phased-array receiver with 14-bit phase & gain manager and calibration-free dual-mode 28-52dB image rejection ratio for 5G NR,” inIEEE Custom Integrated Circuits Conf. (CICC), Newport Beach, CA, USA, Apr. 2022. (CICC2022 Best Student Paper Award Finalist)

C3 J. Zhou,H. Qian, et al, “A phase-modulation phase-shifting phased-array transmitter with 10-bit fast-locking phase self-calibration and 0/2.5/6/12dB power back-offs efficiency enhancement,” inIEEE Custom Integrated Circuits Conf. (CICC), Newport Beach, CA, USA, Apr. 2022.

C4 B. Yang,H. Qian, et al, “22-30GHz quadrature hybrid SCPA with LO leakage self-suppression and distributed parasitic-cancelling sub-PA array for linearity and efficiency enhancement,” inIEEE Custom Integrated Circuits Conf. (CICC), Newport Beach, CA, USA, Apr. 2022.

C5 B. Yang,H. Qian, et al, “Watt-level triple-mode quadrature SFCPA with 56 peaks for ultra-deep PBO efficiency enhancement using IQ intrinsic interaction and adaptive phase compensation,” inIEEE Custom Integrated Circuits Conf. (CICC), Newport Beach, CA, USA, Apr. 2022.

C6 J. Zhou,H. Qian, et al, “A quadrature-rotation phased-array transmitter with 15-bit phase tuning and 0/3/6/9/12/15-dB PBOs efficiency enhancement,” inIEEE RFIC, Denver, CO, USA, Jun. 2022.

C7 W. Chen, Y. Shu,H. Qian,et al, “A 21.8–41.6GHz fast-locking sub-sampling PLL with dead zone automatic controller achieving 62.7-fs Jitter and –250.3dB FoM,” inIEEE RFIC, Denver, CO, USA, Jun. 2022. (RFIC2022 Best Student Paper Award Finalist)

C8 H. Tang,H. Qian, et al, “A polar Doherty SCPA with 4.4º AM-PM distortion using on-chip self-calibration supporting 64-/256-/1024-QAM,” inIEEE RFIC, Denver, CO, USA, Jun. 2022.

C9 C. Pi,H. Qian, et al, “A 140-500 GHz CMOS THz spectroscope with 1 MHz resolution based on multi-branch rotational symmetric sensing surface,” inIEEE MTT-S Int. Microwave Sym. Dig., Denver, CO, USA, Jun. 2022.

C10 Y. Rao,H. Qian, et al, “Miniaturized 28 GHz packaged bandpass filter with high selectivity and wide stopband using multi-layer PCB technology,” inIEEE MTT-S Int. Microwave Sym. Dig., Denver, CO, USA, Jun. 2022. (IMS2022 Best Student Paper Award Finalist, IMS Top50 Paper)

C11 Y. Shu,H. Qian, et al, “A 2.3-to-3.2GHz Class-G impedance-modulation power oscillator with 10dBm peak pout and 39%/37%/33%/30% efficiency at 0/3/6/9dB PBOs,” inIEEE RFIC, Atlanta, GA, USA, Jun. 2021.

C12 Z. Deng,H. Qian, et al, “A 3.6dB NF, 23–39GHz reflectionless RX with absorptive amplifier and dual-path noise cancelling LNA supporting 64-QAM/256-QAM/1024-QAM for 5G NR,” inIEEE Custom Integrated Circuits Conf. (CICC), Virtual, Apr. 2021.

C13 B. Yang,H. Qian, et al, “A watt-level quadrature switched/floated capacitor power amplifier with back-off efficiency enhancement in complex domain using reconfigurable self-canceling transformer,” inIEEE ISSCC, San Francisco, CA, Feb. 2021.

C14 Y. Shu,H. Qian, et al, “A 3.09-to-4.04GHz distributed-boosting and harmonic-impedance-expanding multi-core oscillator with -138.9dBc/Hz at 1MHz offset and 195.1dBc/Hz FoM,” inIEEE ISSCC, San Francisco, CA, Feb. 2021. (ISSCC2021 RF Session Highlight)

C15 Y. Shu,H. Qian, et al, “A 18.6-to-40.1GHz, 201.7dBc/Hz FoMT multi-core oscillator using E-M mixed-coupling resonance boosting,” inIEEE ISSCC, San Francisco, CA, Feb. 2020.

C16H. Qian, et al, “A quadrature digital power amplifier with hybrid Doherty and impedance boosting for efficiency enhancement in complex domain,” inIEEE RFIC, Los Angeles, CA, USA, Jun. 2020.

C17 B. Yang,H. Qian, et al, “1.2–3.6 GHz 32.67 dBm 4096-QAM digital PA using reconfigurable power combining transformer for wireless communication,” inIEEE RFIC, Los Angeles, CA, USA, Jun. 2020.

C18 D. Tang, C. Han, Z. Deng,H. Qian, et al, “Compact bandpass filter with wide stopband and low radiation loss using substrate integrated defected ground structure,” inIEEE MTT-S Int. Microwave Sym. Dig., Los Angeles, CA, USA, Jun. 2020. (IMS2020 Best Student Paper Finalist)

C19H. Qian, et al, “A 20-32GHz digital quadrature transmitter with notched matching and mode-switch topology for 5G wireless and backhaul system,” inIEEE RFIC, Boston, MA, USA, Jun. 2019.

C20 B. Yang,H. Qian, et al, “A 90-98 GHz 2×2 phased-array transmitter with high resolution phase control and digital gain compensation,” inIEEE MTT-S Int. Microwave Sym. Dig., Boston, MA, USA, Jun. 2019. (IMS2019 Best Student Paper Award Finalist)

C21 W. Chen, Y. Shu, Z. Deng,H. Qian, et al, “A wideband quasi-circulator with low NF and high P1dB using noise-canceling technique,” inIEEE MTT-S Int. Microwave Sym. Dig., Boston, MA, USA, Jun. 2019.

C22 J. Ren,H. Qian, et al, “A wideband filtering balun using CPW-to-slotline transitions,” inIEEE MTT-S Int. Microwave Sym. Dig., Philadelphia, PA, USA, Jun. 2018. (IMS2018 Best Student Paper Award Finalist)

C23 Y. Shu,H. Qian, et al, “A 169.6 GHz hybrid mode-switching push-push oscillator with 21.7% tuning range and 180.6dBc/Hz FoMTin 28nm CMOS technology,” inIEEE MTT-S Int. Microwave Sym. Dig., Philadelphia, PA, USA, Jun. 2018.

C24 Z. Deng,H. Qian, et al, “A compact quasi-circulator with high isolation using reconfigurable 180° hybrid,” inIEEE MTT-S Int. Microwave Sym. Dig., Philadelphia, PA, USA, Jun. 2018.

C25 Y. Shu,H. Qian, et al, “A 20.7-31.8GHz dual-mode voltage waveform-shaping oscillator with 195.8dBc/Hz FoMTin 28nm CMOS,” inIEEE RFIC, Philadelphia, PA, USA, Jun. 2018.

C26H. Qian, et al, “A 3-7GHz 4-Element Digital Modulated Polar Phased-Array Transmitter with 0.35° Phase Resolution and 38.2% Peak System Efficiency”, inIEEE Custom Integrated Circuits Conference (CICC),Austin, Texas, USA, Apr. 2017.

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