Conventional and novel approaches to RF power generation with two-terminal devices at terahertz frequencies

Proceedings, IEEE Tenth International Conference on Terahertz Electronics Pub Date : 2002-11-07 DOI:10.1109/THZ.2002.1037576

H. Eisele

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引用次数: 3

Abstract

Recent advances in design and technology significantly improved the performance of low-noise InP Gunn devices in oscillators at W-band (75-110 GHz) and D-band (110-170 GHz) frequencies. More importantly, they resulted in orders of magnitude higher radio-frequency (RF) output power levels above D-band. Examples are continuous-wave RF power levels of more than 30 mW at 193 GHz, more than 3 mW at 300 GHz, and more than 1 mW at 315 GHz. The DC power requirements of these oscillators compare favorably with those of RF sources driving frequency multiplier chains to reach the same output RF power levels and frequencies. Generation of significant RF power levels from InP Gunn devices is predicted up to at least 500 GHz. A different approach to a Gunn-like device for even higher frequencies is based on a heterostructure perpendicular to a superlattice. Tunnel injection transit-time (TUNNETT) diodes are another candidate for low-noise RF sources at submillimeter-wave frequencies. Low-noise GaAs TUNNETT diodes, for example, already yielded more than 10 mW at 202 GHz, but more recent material systems such as GaN show more favorable material parameters than GaAs.

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太赫兹频率双端射频发电的传统和新方法

设计和技术的最新进展显著提高了w波段(75-110 GHz)和d波段(110-170 GHz)振荡器中低噪声InP - Gunn器件的性能。更重要的是，它们使d波段以上的射频(RF)输出功率水平提高了几个数量级。例如，连续波射频功率水平在193 GHz时超过30 mW，在300 GHz时超过3 mW，在315 GHz时超过1 mW。为了达到相同的输出射频功率水平和频率，这些振荡器的直流功率要求与驱动倍频链的射频源相比是有利的。预计InP - Gunn器件产生的显著射频功率水平至少可达500 GHz。另一种用于更高频率的类似gunn装置的方法是基于垂直于超晶格的异质结构。隧道注入传输时间(TUNNETT)二极管是亚毫米波频率下低噪声射频源的另一个候选。例如，低噪声GaAs TUNNETT二极管在202ghz下已经产生了超过10mw的功率，但最近的材料系统(如GaN)显示出比GaAs更有利的材料参数。

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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Proceedings, IEEE Tenth International Conference on Terahertz Electronics

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