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Ka波段增强型负载调制的超宽带高效率Doherty功率放大器研究

杨琳 闫成宇 王彦平 张明 王保柱 韩琦 何宇航 侯卫民 李康

杨琳, 闫成宇, 王彦平, 张明, 王保柱, 韩琦, 何宇航, 侯卫民, 李康. Ka波段增强型负载调制的超宽带高效率Doherty功率放大器研究[J]. 电子与信息学报. doi: 10.11999/JEIT260514
引用本文: 杨琳, 闫成宇, 王彦平, 张明, 王保柱, 韩琦, 何宇航, 侯卫民, 李康. Ka波段增强型负载调制的超宽带高效率Doherty功率放大器研究[J]. 电子与信息学报. doi: 10.11999/JEIT260514
YANG Lin, YAN Chengyu, WANG Yanping, ZHANG Ming, WANG Baozhu, HAN Qi, HE Yuhang, HOU Weimin, LI Kang. Research on Ka-band Enhanced Load Modulation Ultra-wideband High-efficiency Doherty Power Amplifier[J]. Journal of Electronics & Information Technology. doi: 10.11999/JEIT260514
Citation: YANG Lin, YAN Chengyu, WANG Yanping, ZHANG Ming, WANG Baozhu, HAN Qi, HE Yuhang, HOU Weimin, LI Kang. Research on Ka-band Enhanced Load Modulation Ultra-wideband High-efficiency Doherty Power Amplifier[J]. Journal of Electronics & Information Technology. doi: 10.11999/JEIT260514

Ka波段增强型负载调制的超宽带高效率Doherty功率放大器研究

doi: 10.11999/JEIT260514 cstr: 32379.14.JEIT260514
基金项目: 国家自然科学基金(62441401),国家重点研发计划(2022YFB4400400),国家重点实验室基础科学研究创新基金(IFN20230113),河北省重大科技支撑项目(24290201Z),河北省自然科学基金(F2024208020),河北省教育厅青年拔尖人才项目(BJK2024089)
详细信息
    作者简介:

    杨琳:女,副教授,博士,硕士生导师,研究方向为无线通信前端芯片技术,微波毫米波集成电路

    闫成宇:男,硕士研究生,研究方向为微波毫米波功率放大器技术

    王彦平:男,研究员,博士,博士生导师,研究方向为雷达成像安全监测技术、遥感智能信息处理及应用

    张明:男,副教授,博士,硕士生导师,研究方向为电磁波调控,可重构超表面天线

    王保柱:男,教授,博士,硕士生导师,研究方向为微电子与光电子技术、半导体材料与器件、电路与系统应用

    韩琦:男,讲师,博士,硕士生导师,研究方向为光通信芯片和太赫兹探测器

    何宇航:男,讲师,博士,硕士生导师,研究方向为新型半导体材料的太赫兹光子学、电磁超材料的设计与调控

    侯卫民:男,教授,博士,硕士生导师,研究方向为阵列信号处理、无线通信

    李康:男,副教授,博士,硕士生导师,研究方向为毫米波功率器件、太赫兹器件

    通讯作者:

    侯卫民 jerry.ioa.bj@hotmail.com

  • 中图分类号: TN43

Research on Ka-band Enhanced Load Modulation Ultra-wideband High-efficiency Doherty Power Amplifier

Funds: National Natural Science Foundation of China (No.62441401),National Key Research and Development Program of China (No. 2022YFB4400400), National Key Laboratory of Basic Scientific Research for Innovation Fund (No. IFN20230113), Major Science and Technology Support Project of Hebei Province (No.24290201Z), Hebei Natural Science Foundation (No. F2024208020), Science and Technology Project of Hebei Education Department (No. BJK2024089)
  • 摘要: Ka波段是未来新一代高通量卫星的核心频段,卫星通信发射系统对功率放大器提出了高回退效率的严苛要求。Doherty功率放大器(DPA)通过有源负载调制显著提高了功率回退状态下的工作效率,但Doherty架构的固有阻抗变换网络严重限制了其工作带宽,同时,其在毫米波段的饱和与回退效率均大幅下降,这成为制约其在毫米波高通量卫星通信系统中应用的关键瓶颈。针对上述问题,本文提出了一种超宽带增强型有源负载调制技术,有效突破Doherty功率放大器带宽和回退效率相互制约的瓶颈,实现毫米波Doherty架构的效率增强和带宽扩展。同时,创新的提出了一种超宽带相位补偿非等分功率分配网络,扩展了高效率带宽,同时缩小了芯片面积。为验证所提理论,基于0.15 μm GaN工艺,设计了一款毫米波超宽带高效率Doherty功率放大器芯片,最终在24-33 GHz(相对带宽达到31.6%)的超宽频带内,实现了21.8-23.8 dB的小信号增益,28.9-31.0 dBm的饱和输出功率,饱和功率附加效率(PAE)为25.2%-33.5%,6dB回退PAE为15.5%-19.8%。在目前所报道的相近频带的毫米波GaN Doherty功放中,具有最高的小信号增益及饱和PAE,高的饱和输出功率和6 dB回退PAE等一系列优异性能,同时在目前所报道的2-3级DPA芯片中具有最小的芯片面积。
  • 图  1  载波与峰值晶体管最佳负载阻抗空间

    图  2  提出的新型超宽带增强型有源负载调制网络

    图  3  载波与峰值功放输入/输出功率仿真结果

    图  4  所提出的超宽带PCPDN与传统结构对比图

    图  5  提出的新型超宽带PCPDN和传统的相位补偿传输线效果对比

    图  6  三级毫米波超宽带紧凑型高效率Doherty功率放大器简化结构图

    图  7  24-33 GHz超宽带高效率Doherty功率放大器芯片照片

    图  8  芯片S参数及PAE随输入功率变化测试结果

    图  9  芯片输出功率及功率增益随输入功率变化、饱和输出功率、饱和PAE及6dB回退PAE测试结果

    表  1  与目前报道的毫米波GaN DPA MMIC性能对比表

    参考
    文献
    频率
    (GHz)
    相对带宽(%)级数Psat
    (dBm)
    增益
    (dB)
    PAE(%)
    @Psat
    PAE(%)@
    6dB PBO
    芯片面积(mm2)年份所采用工艺
    [11]24-2815.4236.8-38.116.4-2029.7-36.818.6-32a7.4420240.15um GaN
    [15]24-2815.4235.4-3614.9-19.727.8-36.818.1-30.15.9520220.15um GaN
    [16]24-3022.2231.6-32.79.8-14.920-27.618.2-22.46.320250.12um GaN
    [17]24-2918.9234.8-36.115.7-19.525-31.719-24.85.3220240.15um GaN
    [18]28-29.55.2334.613242111.7820240.15um GaN
    [19]29.1-130944285.3820220.15um GaN
    本文24-3331.6328.9-31.021.8-23.825.2-33.515.5-19.84.0520260.15um GaN
    注:a:8dB回退效率
    下载: 导出CSV
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出版历程
  • 收稿日期:  2026-04-27
  • 修回日期:  2026-06-24
  • 录用日期:  2026-06-24
  • 网络出版日期:  2026-07-02

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