基于阻抗补偿技术的毫米波超宽带功分器

卢启军; 韩大伟; 张浩; 张涛; 朱樟明

doi:10.12263/DZXB.20240555

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基于阻抗补偿技术的毫米波超宽带功分器

学术论文 | 更新时间：2025-12-08

- 基于阻抗补偿技术的毫米波超宽带功分器
- Millimeter-Wave Ultra-Wideband Power Divider with Impedance Compensation Technique
- 电子学报 2025年53卷第1期页码：112-118
- 作者机构：
  
  1.西安电子科技大学集成电路学院模拟集成电路与系统教育部重点实验室，陕西西安 710071
  2.南京电子技术研究所，江苏南京 210013
- 作者简介：
  
  [ "卢启军男，1986年8月出生于陕西省渭南市.现为西安电子科技大学集成电路学部副教授、硕士生导师.主要研究方向为硅基微波/毫米波集成电路与系统. E-mail: qjlu@xidian.edu.cn" ]
  [ "韩大伟男，2000年7月出生于山东省菏泽市.现为西安电子科技大学集成电路学部硕士研究生.主要研究方向为相控阵射频集成电路系统.E-mail: dwhan@stu.xidian.edu.cn" ]
  [ "张浩男，1982年12月出生于河南省郑州市.现为南京电子技术研究所正高级工程师.主要研究方向为射频微波、数模混合SOC集成电路. E-mail: zhhseu@163.com" ]
  [ "张涛男，1987年6月出生于浙江省绍兴市.现为西安电子科技大学集成电路学部副教授、博士生导师.主要研究方向为射频/毫米波系统与天线一体化集成.中国电子学会会员编号：E190030161M. E-mail: zhangt@xidian.edu.cn" ]
  [ "朱樟明男，1978年1月出生于浙江省嵊州市.现为西安电子科技大学集成电路学部教授、博士生导师.主要研究方向为射频集成电路与系统高能效模数转换器.中国电子学会会员编号：E190013050S.E-mail: zmyh@263.net" ]
- 基金信息：
  
  国家自然科学基金(62074121;62034002;62021004;62274133);陕西省教育厅科研计划项目(20JY018)
- DOI：10.12263/DZXB.20240555
  中图分类号： TN771;TN958
- 收稿：2024-06-13，
  
  修回：2024-08-20，
  
  纸质出版：2025-01-25
- 稿件说明：
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卢启军, 韩大伟, 张浩, 等. 基于阻抗补偿技术的毫米波超宽带功分器[J]. 电子学报, 2025, 53(01): 112-118.

LU Qi-jun, HAN Da-wei, ZHANG Hao, et al. Millimeter-Wave Ultra-Wideband Power Divider with Impedance Compensation Technique[J]. Acta Electronica Sinica, 2025, 53(01): 112-118.
卢启军, 韩大伟, 张浩, 等. 基于阻抗补偿技术的毫米波超宽带功分器[J]. 电子学报, 2025, 53(01): 112-118. DOI：10.12263/DZXB.20240555

LU Qi-jun, HAN Da-wei, ZHANG Hao, et al. Millimeter-Wave Ultra-Wideband Power Divider with Impedance Compensation Technique[J]. Acta Electronica Sinica, 2025, 53(01): 112-118. DOI：10.12263/DZXB.20240555

摘要

针对宽带功率分配器面积大、回波损耗差等问题，本文提出了一款基于阻抗补偿技术的毫米波超宽带威尔金森功率分配器.在传统集总功分器输出端口添加并联LC谐振网络，可以补偿功分器的输入和输出阻抗并引入额外的匹配和无损耗频率点，进而有效地提高功分器的分数带宽.提出的功率分配器采用65 nm互补金属氧化物半导体（Complementary Metal Oxide Semiconductor，CMOS）工艺设计并测试验证，核心面积紧凑，仅有0.021 mm

.测试结果表明，该功分器的插入损耗为1.35~1.55 dB，0.2-dB幅度带宽为44~96 GHz，输入输出回波损耗和隔离性能在整个工作频段内均优于11 dB.与已发布的毫米波功率分配器相比，提出的功率分配器在保持良好端口匹配的同时实现了较高的幅度带宽.

Abstract

In this paper

a millimeter-wave ultra-wideband Wilkinson power divider with impedance compensation technique is presented. After adding parallel LC resonance networks at the output ports of traditional lumped-element power divider

the bandwidth can be increased effectively by compensating the input-output impedance and introducing additional matching and lossless frequency points. The proposed power divider is implemented using 65 nm complementary metal oxide semiconductor (CMOS) technology with a compact core area of 0.021 mm

. And the measurement results indicate that the insertion loss is 1.35~1.55 dB

reaching 0.2-dB amplitude bandwidth of 44~96 GHz

as well as the input-output return loss and isolation performance are all better than 11 dB across the entire operating frequency band. The proposed power divider achieves higher amplitude bandwidth with good port matching compared to previously published power dividers.

关键词

Keywords

references

LEE J G , JANG T H , PARK G H , et al . A 60-GHz four-element beam-tapering phased-array transmitter with a phase-compensated VGA in 65-nm CMOS [J ] . IEEE Transactions on Microwave Theory and Techniques , 2019 , 67 ( 7 ): 2998 - 3009 .

徐仲麟 , 吴林晟 , 佘胜团 , 等 . 面向低轨卫星通信的K波段LTCC多通道集成接收前端模块 [J ] . 电子学报 , 2022 , 50 ( 6 ): 1389 - 1398 .

XU Z L , WU L S , SHE S T , et al . A K-band LTCC multi-channel integrated receiving front-end module for low earth orbit satellite communication [J ] . Acta Electronica Sinica , 2022 , 50 ( 6 ): 1389 - 1398 . (in Chinese)

GU P , ZHAO D X , YOU X H . Analysis and design of a CMOS bidirectional passive vector-modulated phase shifter [J ] . IEEE Transactions on Circuits and Systems I: Regular Papers , 2021 , 68 ( 4 ): 1398 - 1408 .

李虹萍 , 陈海东 , 薛泉 , 等 . 多路任意功分比Gysel功分器 [J ] . 电子学报 , 2022 , 50 ( 2 ): 383 - 390 .

LI H P , CHEN H D , XUE Q , et al . N-way Gysel power divider with arbitrary power dividing ratio [J ] . Acta Electronica Sinica , 2022 , 50 ( 2 ): 383 - 390 . (in Chinese)

KIM K , NGUYEN C . A V-band power amplifier with integrated Wilkinson power dividers-combiners and transformers in 0.18-μm SiGe BiCMOS [J ] . IEEE Transactions on Circuits and Systems II: Express Briefs , 2019 , 66 ( 3 ): 337 - 341 .

LIU H , ZHU X , WANG Y S , et al . A 60 GHz 8-way combined power amplifier in 0.18 μm SiGe BiCMOS [J ] . IEEE Transactions on Circuits and Systems II: Express Briefs , 2021 , 68 ( 6 ): 1847 - 1851 .

LEE S , PARK J , HONG S . A 24-30 GHz low-loss compact differential four-way power divider [C ] // 2021 IEEE MTT-S International Microwave Symposium (IMS) . Piscataway : IEEE , 2021 : 492 - 495 .

KUO C Y , CHEN A Y K , LI C Z , et al . A mm-wave stub-loaded ECPW Wilkinson power divider/combiner in 90 nm CMOS [J ] . IEEE Microwave and Wireless Components Letters , 2012 , 22 ( 12 ): 627 - 629 .

LIN Y S , LAN K S . Realization of a compact and high-performance power divider using parallel RC isolation network [J ] . IEEE Transactions on Circuits and Systems II: Express Briefs , 2021 , 68 ( 4 ): 1368 - 1372 .

EL-HAMEED A S ABD , BARAKAT A , ABDEL-RAHMAN A B , et al . Design of low-loss coplanar transmission lines using distributed loading for millimeter-wave power divider/combiner applications in 0.18 μm CMOS technology [J ] . IEEE Transactions on Microwave Theory and Techniques , 2018 , 66 ( 12 ): 5221 - 5229 .

PARK J S , WANG H . A fully differential ultra-compact broadband transformer-based Wilkinson power divider [J ] . IEEE Microwave and Wireless Components Letters , 2016 , 26 ( 4 ): 255 - 257 .

KIM K , NGUYEN C . An ultra-wideband low-loss millimeter-wave slow-wave Wilkinson power divider on 0.18 μm SiGe BiCMOS process [J ] . IEEE Microwave and Wireless Components Letters , 2015 , 25 ( 5 ): 331 - 333 .

HSIAO C Y , WU C T M , KUO C N . A W-band 1-dB insertion loss Wilkinson power divider using silicon-based integrated passive device [J ] . IEEE Microwave and Wireless Components Letters , 2021 , 31 ( 6 ): 654 - 657 .

HONARI M M , MIRZAVAND L , MIRZAVAND R , et al . Theoretical design of broadband multisection Wilkinson power dividers with arbitrary power split ratio [J ] . IEEE Transactions on Components, Packaging and Manufacturing Technology , 2016 , 6 ( 4 ): 605 - 612 .

LIN Y S , LAN K S , CHEN B S . Wideband millimeter-wave power divider and SPDT switch using inverting spiral-coupled-line [J ] . IEEE Transactions on Circuits and Systems II: Express Briefs , 2023 , 70 ( 4 ): 1575 - 1579 .

CHOI U G , YANG J R . A D-band two-way differential power divider on 65-nm CMOS process [J ] . IEEE Microwave and Wireless Technology Letters , 2024 , 34 ( 3 ): 279 - 282 .

LEE S , PARK J , HONG S . Millimeter-wave multi-band reconfigurable differential power divider for 5G communication [J ] . IEEE Transactions on Microwave Theory and Techniques , 2022 , 70 ( 1 ): 886 - 894 .

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