Ultra-Wideband Transceiver MMIC Tuneable From 74.1 GHz to 147.8 GHz in SiGe Technology

IF 6.9 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Florian Vogelsang;Jonathan Bott;David Starke;Christian Bredendiek;Klaus Aufinger;Nils Pohl
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Abstract

As the use of integrated radar sensors is becoming more common not only in traditional military and automotive but also in medical and industrial applications, the requirements for a radar sensor diversify. For some applications, bandwidth is critical, primarily defining the capability to distinguish targets. Mostly, varying the frequency of an oscillator in the mmWave and THz range is realized by tuning a dc voltage to a variable capacitance. While this is typical for integrated transceivers in silicon-germanium (SiGe) technology, the tunability of a single voltage-controlled oscillator (VCO) limits the bandwidth. This work presents an approach to overcome this limitation by using two simultaneously tuned VCOs combined with a mixer. The oscillators are tuned simultaneously in opposing directions, resulting in an ultra-wideband signal at the mixer's output. The resulting tuning range is the addition of both of the VCOs' respective tuning ranges. The transceiver is realized using the B11HFC SiGe technology, featuring VCOs at center frequencies of 52 GHz and 108 GHz, respectively. The transceivers' output with a center frequency of 111 GHz is continuously tunable over a range of 73.6 GHz (66%). Furthermore, the phase noise contributions from both VCOs along a receiver test are presented.
采用 SiGe 技术的超宽带收发器 MMIC 可从 74.1 GHz 调谐到 147.8 GHz
随着集成雷达传感器的使用越来越普遍,不仅在传统的军事和汽车领域,而且在医疗和工业应用领域,对雷达传感器的要求也越来越多样化。在某些应用中,带宽至关重要,主要决定了分辨目标的能力。在毫米波和太赫兹范围内,改变振荡器的频率通常是通过调整直流电压到可变电容来实现的。虽然这对于硅锗(SiGe)技术的集成收发器来说很典型,但单个压控振荡器(VCO)的可调谐性限制了带宽。这项研究提出了一种克服这一限制的方法,即使用两个同时调谐的压控振荡器和一个混频器。振荡器同时向相反方向调谐,从而在混频器输出端产生超宽带信号。由此产生的调谐范围是两个 VCO 各自调谐范围的总和。收发器采用 B11HFC SiGe 技术实现,其 VCO 的中心频率分别为 52 GHz 和 108 GHz。收发器的输出中心频率为 111 GHz,可在 73.6 GHz(66%)的范围内连续调谐。此外,还介绍了两个 VCO 在接收器测试中的相位噪声贡献。
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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