华南理工大学

徐金旭

发布日期:2024-05-03 浏览次数:

更新日期:2024年3月12日 姓 名 徐金旭 性 别 男 出生年月 籍贯 广东梅州市 民 族 汉族 政治面貌 群众 最后学历 博士研究生 最后学位 哲学博士 技术职称 副教授 导师类别 博、硕导 行政职务 Email xujinxu@scut.edu.cn 工作单位 华南理工大学微电子学院 邮政编码 通讯地址 单位电话 个人主页 https://www2.scut.edu.cn/microelectronics/2020/0910/c25586a421212/page.htm 个人简介 徐金旭,华南理工大学副教授、博导,悉尼科技大学和华南理工大学双博士学位,入选中国科协“青年人才托举工程”,获得中国电子学会优秀博士学位论文。主要从事微波毫米波电路与子系统方面的研究工作,参与了企业委托横向项目,并实现了部分射频电路与芯片的成果产业化应用;发表SCI/EI论文70余篇,其中包括第一/通讯作者的IEEE Trans.期刊论文21篇;获得中国发明专利授权30余项,美国专利授权4项;作为参与成员获得2020年度广东省技术发明一等奖、2021年广东省电子信息行业科技进步一等奖、2020年粤港澳大湾区高价值专利培育布局大赛金奖;获得2016年IEEE MTT-S IMWS-AMP及2019年ICMMT国际会议论文奖;担任SCI期刊IET Circuits, Devices and Systems副编辑,SCI期刊Microwave and Optical Technology Letters客座编辑以及国内期刊《微波学报》首届青年编委。主持了国家自然科学基金青年/面上/重点(参与高校方负责人)、重点研发计划任务/子课题等项目。 工作经历  2022.06 ~ 华南理工大学 副教授 2021.12 – 2022.05 澳门大学珠海研究院 副研究员 2020.11 – 2021.11 澳门大学 博士后 教育经历  2018.09 – 2020.03 悉尼科技大学 博士(双学位) 2015.09 – 2019.12 华南理工大学 博士 2011.09 – 2015.06 华南理工大学 本科 获奖、荣誉称号 1.     入选中国科协”青年人才托举工程“2. 中国电子学会优秀博士学位论文,2020年3. 广东省技术发明一等奖,2020年,排名:11/154. 广东省电子信息行业科技进步一等奖,2021年,排名:6/115. 粤港澳大湾区高价值专利培育布局大赛金奖,2020年,排名:7/9 6. 第二届青年交叉创新创业交流会优秀报告奖,2023年,排名1/17. IEEE IMWS-AMP国际会议论文奖(第一作者),主办单位:国际微波理论与技术协会(IEEE MTT-S), 2016年8. ICMMT 2019国际微波毫米波会议论文奖(第二作者), 主办单位:中国电子学会,2019年9. FEIT HDR Post Thesis Publication Award, 授予单位:悉尼科技大学,2020年 社会、学会及学术兼职 1.     TPC Co-Chair, 程序册委员会共同主席:2021 IEEE International Workshop on Electromagnetics (iWEM2021), Guangzhou, China.2. 广东省天线与射频技术工程技术研究中心副主任3. IEEE广州AP/MTT Chapter副主席(Vice Chair)4. 国际国内期刊编辑:          《微波学报》首届青年编委         IET Circuits, Devices & Systems(Associate Editor)         Microwave and Optical Technology Letters(Guest Editor)5. IEEE TMTT/TCAS1/TIE等10余个期刊国际审稿人 研究领域 射频电路、微波毫米波前端芯片与子系统 科研项目 1. 国家自然科学基金面上项目,基于协同融合的异构集成多功能前端芯片及模组关键技术研究,62371193,直接经费:49万,2024.01-2027.12,主持2. 国家自然科学基金青年基金,基于介质谐振器的单体双路/多路滤波电路研究,直接经费:24万元,2021.01-2023.12,主持3. 国家自然科学基金重点项目,基于薄膜集成与薄膜体声波的异构集成射频无源电路研究,经费120万元,2023.01-2027.12,参与高校方负责人 发表论文 [1] J.-X. Xu, H. Chen, W. Chen, and X. Y. Zhang, “Broadband Doherty power amplifier using short ended λ/4 transmission lines based on the analysis of negative characteristic impedance,” IEEE Trans. Circuits and Systems I - Regular Papers, vol. 70, no. 2, pp. 545-555, Feb. 2023. [2] J.-X. Xu and X. Y. Zhang, Dual-channel dielectric resonator filter and its application to Doherty power amplifier for 5G massive MIMO system, IEEE Transactions on Microwave Theory and Techniques, vol. 66, no. 7, pp. 3297-3305, July 2018.[3] J. Zhang, J.-X. Xu*, C. Yao, and X. Y. Zhang, “Miniaturized high-selectivity high-resistivity-silicon IPD bandpass filter based on multiple transmission paths,” IEEE Electron Device Letters, early access, 2024.[4] P. Zhang#, S. Zhang#, J.-X. Xu#, X. Fang, Y. Chen, K. Huang, D. Sui, X. Y. Zhang, X. Ou, “Miniaturized dual-mode SAW filters using 6-inch LiNbQ3-on-SiC for 5G NR and WiFi 6”, 2023 IEEE International Electron Devices Meeting (IEDM), 2023.[5] W. Zeng, L. Gao, N-Z. Sun, H.-Y. Li, J.-X. Xu, H. Xu, Q. Xue, and X. Y. Zhang, “A compact 19.7- to 43.8-GHz power amplifier with 20.3-dBm Psat and 35.5% PAE in 28-nm bulk CMOS,” IEEE Journal of Solid-State Circuits, early access, 2024.[6] H.-Y. Li, J.-X. Xu*, and X. Y. Zhang, “A Ku-band image-rejection filtering LNA MMIC in 150-nm GaN-on-SiC technology,” Science China Information Sciences, Jan. 2024.[7] H.-Y. Li, J.-X. Xu, L. Gao, Q. Xue, and X. Y. Zhang, “24-35 GHz filtering LNA and filtering switch using compact mixed magnetic-electric coupling circuit in 28-nm bulk CMOS,” IEEE Trans. Circuits and Systems I - Regular Papers, vol. 70, no. 3, pp. 1071-1082, Mar. 2023.[8] H.-T. Lin, L. Gao, H.-Y. Li, J.-X. Xu, and X. Y. Zhang, “A 23.6-46.5 GHz LNA with 3 dB NF and 24 dB gain tuning range in 28-nm CMOS technology,” IEEE Trans. Circuits and Systems I - Regular Papers, early access, 2023.[9] J.-X. Xu, X. Y. Zhang, H.-Y. Li, Y. Yang, E. Dutkiewicz, and Q. Xue, “Ultra-compact multi-channel bandpass filter based on tri-mode dielectric-loaded cavities,” IEEE Transactions on Microwave Theory and Techniques, vol. 68, no. 5, pp. 1668-1677, Mar. 2020. [10] J.-X. Xu, L. Yang, Y. Yang, and X. Y. Zhang, High-Q-factor tunable bandpass filter with constant absolute bandwidth and wide tuning range based on coaxial resonators, IEEE Transactions on Microwave Theory and Techniques, vol. 67, no. 10, pp. 4186-4195, Oct. 2019.[11] J.-X. Xu, H.-Y. Li, X. Y. Zhang, Y. Yang, Q. Xue and E. Dutkiewicz, Compact dual-channel balanced filter and balun filter based on quad-mode dielectric resonator, IEEE Transactions on Microwave Theory and Techniques, vol. 65, no. 11, pp. 4636-4644, Feb. 2019. [12] J.-X. Xu and X. Y. Zhang, Compact High-Isolation LTCC Diplexer Using Common Stub-Loaded Resonator With Controllable Frequencies and Bandwidths, IEEE Transactions on Microwave Theory and Techniques, vol. 65, no. 11, pp. 4636-4644, Nov. 2017.[13] J.-X. Xu, X. Y. Zhang and H.-Y. Li, Compact narrow-band filtering rat-race coupler using quad-mode dielectric resonator, IEEE Transactions on Microwave Theory and Techniques, vol. 66, no. 9, pp. 4029-4039, Aug. 2018. [14] J.-X. Xu, M. Huang, W.-L. Zhan, and X. Y. Zhang, “Reconfigurable filtering power divider with arbitrary operating channels based on external quality factor control,” IEEE Transactions on Circuits and Systems I: Regular Papers, vol. 69, no. 11, pp. 4395-4403, Nov. 2022.[15] J.-X. Xu and X. Y. Zhang, Single- and Dual-Band LTCC Filtering Switch With High Isolation Based on Coupling Control, IEEE Transactions on Industrial Electronics, vol. 64, no. 4, pp. 3137-3146, April 2017. [16] H.-Y. Li, J.-X. Xu*, and X. Y. Zhang, “Substrate integrated waveguide filtering rat-race coupler based on orthogonal degenerate modes,” IEEE Transactions on Microwave Theory and Techniques, vol. 67, no. 1, pp. 140-150, Jan. 2019.[17] H.-Y. Li, J.-X. Xu*, Y. Yang, and X. Y. Zhang, “Novel switchable filtering circuit with function reconfigurability between SPQT filtering switch and four-way filtering power divider,” IEEE Transactions on Microwave Theory and Techniques, vol. 68, no. 3, pp. 867-876, Mar. 2020. [18] H.-Y. Li, J.-X. Xu*, and X. Y. Zhang, “Single-to-balanced and balanced-to-balanced dual-channel filters using multilayer substrate integrated waveguide cavities,” IEEE Transactions on Industrial Electronics, vol. 68, no. 3, pp. 2389-2399, Mar. 2021. [19] X. Y. Zhang, J.-X. Xu and J. X. Chen, High-Power Filtering Switch With Low Loss and High Isolation Based on Dielectric Resonator, IEEE Transactions on Microwave Theory and Techniques, vol. 65, no. 6, pp. 2101-2110, June 2017.[20] H. Chen, J.-X. Xu, and X. Y. Zhang, “Miniaturized broadband Doherty power amplifier using simplified output matching topology,” IEEE Transactions on Circuits and Systems I: Regular Papers, vol. 69, no. 8, pp. 3083-3092, Aug. 2022. 科研创新 美国专利:[1]. Xiu Yin Zhang, Jin-Xu Xu, “High-power filtering switch with low loss and high isolation based on dielectric resonator,” United States Patent, Patent No.: US10283829B2, May 7, 2019. (已授权)[2]. Xiuyin Zhang, Jinxu Xu, and Huiyang Li, “Dual-channel filter based on dielectric resonator,” United States Patent, US11223096B2, Jan. 11, 2022. (已授权)[3]. Xiuyin Zhang, Xiaofeng Liu, Jinxu Xu, and Xiaolan Zhao, “LTCC balun filter using two out-of-phase filtering circuits,” United States Patent, Patent No.: US9786978B2, Oct. 10, 2017. (已授权)[4]. Xiuyin Zhang, Wanli Zhan, Jinxu Xu, Yunfei Cao, “Filtering, power-dividing and phase-shifting integrated antenna array feed network,” United States Patent, Patent No.: US11450951B2, Sep. 20, 2022. (已授权)[5]. Lei Lu, Jian Liang, Xiuyin Zhang, Jinxu Xu, Huiyang Li, Lian Yang, Wanli ZHAN, Zongzhi Gao, Weixi Zhou, “Package Antenna Apparatus and Wireless Communication Apparatus,” United States Patent, Patent No.: US20220320712A1, Oct. 6, 2022. (已受理)中国发明专利:[1]. 徐金旭;章秀银;姚兴晨;李慧阳;电学器件与声学器件混合的滤波器及射频前端;专利号:ZL202310727589.4,2023.12.05[2]. 徐金旭;章秀银;邓旭磊;曾竞涛;黄昆;沓世我;超小型化LTCC双工器及射频前端电路,专利号:ZL202210571719.5,2022.09.23[3]. 徐金旭;章秀银;李慧阳;詹万里;易翔;一种任意通道数量可重构的滤波功分器及射频前端;专利号:ZL2022109497565,授权公告日:2023.09.26[4]. 章秀银;徐金旭;薛艳梅;宋校曲;一种基于介质谐振器的滤波F类功率放大器;专利号:2017102709887,授权公告日:2023.06.16[5]. 章秀银;徐金旭;一种基于介质谐振器的低损耗高隔离滤波开关;专利号:ZL2016112529566,授权公告日:2023.04.21[6]. 章秀银; 徐金旭; 赵小兰, 采用馈电结构来抑制三次谐波的LTCC带通滤波器, 专利号:ZL201410083169.8,授权公告日:2017.01.11[7]. 章秀银; 徐金旭; 刘晓峰; 赵小兰, 一种基于谐振器耦合的LTCC滤波巴伦, 专利号:ZL201410445926.1,授权公告日:2017.06.06[8]. 章秀银;徐金旭;宋校曲,一种基于耦合控制的LTCC滤波开关,专利号:ZL201610630135.5,授权公告日:2020.01.10[9]. 章秀银;徐金旭;薛泉;严格;汪玮玺;一种单体多路滤波开关,专利号:ZL2021106685958,授权公告日:2022.12.09[10]. 赵小兰; 徐金旭; 高立; 章秀银, 一种具有滤波功能的电调功率分配器, 专利号:ZL201410714749.2,授权公告日:2017.06.06[11]. 章秀银;李慧阳;徐金旭,单体双路平衡式滤波器及射频前端电路,专利号:ZL20191026751.5,授权公告日:2024.01.23[12]. 章秀银;詹万里;徐金旭;曹云飞,一种滤波功分移相一体化的天线阵列馈电网络,专利号:ZL2019103888690,授权公告日:2024.01.23[13]. 章秀银;王克龙;徐金旭;宣凯;龙华;低噪声放大电路以及低噪声放大器,专利号:ZL202111454819.1,授权公告日:2022.04.01[14]. 章秀银;王克龙;徐金旭;宣凯;龙华;功率放大器和发射机,专利号:ZL202111456528.6,授权公告日:2022.03.18[15]. 李慧阳;章秀银;徐金旭;小型化滤波低噪声放大器及接收机,专利号:ZL202211195542X,授权公告日:2023.01.06[16]. 章秀银;薄少飞;徐金旭;宣凯;龙华;Doherty功率放大器,专利号:ZL202111417410.2,授权公告日:2022.04.01[17]. 章秀银;李慧阳;徐金旭;宣凯;龙华;滤波低噪声放大器和接收机,专利号:ZL202111428874.3,授权公告日:2022.03.22[18]. 章秀银;李玄平;徐金旭;一种载波功放共用的双频三路Doherty功率放大器;专利号:ZL2018100757876,授权公告日:2023.07.18[19]. 章秀银;薛艳梅;徐金旭;赵小兰;一种基于准集总参数的小型化滤波开关;专利号:ZL2017102707345,授权公告日:2023.04.21[20]. 章秀银;李慧阳;徐金旭;一种基于四模介质谐振器的窄带滤波环形耦合器,专利号:ZL2018105939527,授权公告日:2023.08.18[21]. 章秀银;李慧阳;徐金旭;一种基于正交简并模式的基片集成波导滤波耦合器,专利号:ZL2018107507462,授权公告日:2023.12.01[22]. 章秀银;李慧阳;徐金旭;一种基于介质谐振器的单体双路滤波器,专利号:ZL201711339375.0,授权公告日:2020.12.22[23]. 章秀银; 刘晓峰; 徐金旭; 赵小兰, 一种采用两路反相滤波电路的LTCC滤波巴伦, 专利号:ZL201410446156.2,授权公告日:2017.01.25[24]. 章秀银;杨莲;徐金旭;赵小兰,一种具有恒定绝对带宽的高选择性电调同轴滤波器,专利号:ZL2019101106415,授权公告日:2023.12.05[25]. 章秀银;宋校曲; 徐金旭,一种基于带通带阻混合结构的边带陡峭平面双工器, 专利号:ZL201610630134.0,授权公告日:2020.01.14

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