A D-Band Frequency-Doubling Traveling-Wave Amplifier Through Monolithic Integration of a SiC SIW and GaN HEMTs

IF 6.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Lei Li;Patrick Fay;James C. M. Hwang
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Abstract

We report a solid-state traveling-wave amplifier (TWA) realized through monolithic integration of transistors with a SiC substrate-integrated waveguide (SIW). The TWA uses a stepped-impedance microstrip line as the input divider, but a low-loss, high-power-capacity SIW as the output combiner. The input signal is distributed to four GaN high-electron mobility transistors (HEMTs) evenly in magnitude but with 90° successive phase delays at the fundamental frequency. The HEMTs are distributed in the SIW in a period of a half wavelength at the second harmonic frequency, so that their outputs are combined coherently at the SIW output. To overcome the limited speed of the HEMTs, they are driven nonlinearly to generate second harmonics, and their fundamental outputs are suppressed with the SIW acting as a high-pass filter. The measured characteristics of the TWA agree with that simulated at the small-signal level, but exceeds that simulated at the large-signal level. For example, under an input of 15 dBm at 70 GHz, the output at 140 GHz is 38-dB above that at 70 GHz. Under an input around 70 GHz and 20 dBm, the output around 140 GHz is 14 dBm with a 3-dB bandwidth of 6%. This is not only the first D-band frequency multiplier based on the GaN HEMT technology, but also one with the highest output power and the lowest fundamental leakage among all D-band multipliers of different transistor technologies. This proof-of-principle demonstration opens the path to improve the power, gain and efficiency of sub-terahertz TWAs with higher-performance transistors and drive circuits. Although the demonstration is through monolithic integration, the approach is applicable to heterogeneous integration with the SIW and transistors fabricated on separate chips.
通过单片集成 SiC SIW 和 GaN HEMT 实现 D 波段频率倍增的行波放大器
我们报告了一种固态行波放大器(TWA),它是通过晶体管与碳化硅基底集成波导(SIW)的单片集成实现的。该 TWA 使用阶跃阻抗微带线作为输入分压器,而使用低损耗、高功率容量的 SIW 作为输出合路器。输入信号被均匀地分配到四个 GaN 高电子迁移率晶体管(HEMT)上,但在基频上有 90° 的连续相位延迟。HEMT 在 SIW 中的分布周期为二次谐波频率的半个波长,因此它们的输出在 SIW 输出端相干地结合在一起。为了克服 HEMT 的速度限制,对其进行非线性驱动以产生二次谐波,并利用 SIW 作为高通滤波器抑制其基波输出。TWA 的测量特性与小信号级的模拟特性一致,但超过了大信号级的模拟特性。例如,在 70 GHz 处输入 15 dBm 时,140 GHz 处的输出比 70 GHz 处的输出高出 38 dB。在 70 GHz 附近的 20 dBm 输入下,140 GHz 附近的输出为 14 dBm,3 dB 带宽为 6%。这不仅是首个基于氮化镓 HEMT 技术的 D 波段倍频器,也是所有采用不同晶体管技术的 D 波段倍频器中输出功率最高、基波泄漏最低的一个。这一原理验证为利用更高性能的晶体管和驱动电路提高亚太赫兹 TWA 的功率、增益和效率开辟了道路。虽然演示是通过单片集成进行的,但这种方法也适用于异构集成,即在独立芯片上制造 SIW 和晶体管。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
10.70
自引率
0.00%
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0
审稿时长
8 weeks
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