Principles of low PIM hardware design

Thirteenth National Radio Science Conference. NRSC '96 Pub Date : 1996-03-19 DOI:10.1109/NRSC.1996.551127

T. Khattab, A.D. Rawlins

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引用次数: 13

Abstract

In space RF communications payloads, it is increasingly required that high-power multi-channel transmitters and broadband receivers have shared, or closely adjacent RF feeds. Because of the large power level difference between the transmit and receive signals and the limitation of frequency allocation, passive intermodulation (PIM) interference due to passive non-linearities in the high-power transmission path can be serious problem. One of the main sources of PIM in RF microwave systems is the metal-to-metal contact. A contact model regardless of the suspected non-linear mechanisms, i.e. semiconductor, electron tunnelling and microdischarge, has been used to explain the non-linear effect at metallic contacts. The model requires that the non-linear effect is current dependent and the PIM level is proportional to the current density at the contacts. Because metal-to-metal contact in an RF coaxial connector is unavoidable, an alternative has to be developed. The work reported represents some of our efforts toward developing a demountable RF coaxial connector which does not involve metal-to-metal contact in any electrically significant part, i.e. a "contactless connector". The novel design of the coaxial contactless connector and the theoretical analysis are described.

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低PIM硬件设计原则

在空间射频通信有效载荷中，越来越多地要求高功率多通道发射机和宽带接收器共享或紧密相邻的射频馈电。由于发射和接收信号之间存在较大的功率级差和频率分配的限制，大功率传输路径中由于无源非线性而产生的无源互调(PIM)干扰问题十分严重。射频微波系统中PIM的主要来源之一是金属与金属的接触。一个不考虑半导体、电子隧穿和微放电等非线性机制的接触模型被用来解释金属接触的非线性效应。该模型要求非线性效应依赖于电流，并且PIM水平与触点处的电流密度成正比。由于射频同轴连接器中的金属与金属接触是不可避免的，因此必须开发一种替代方法。报告的工作代表了我们在开发可拆卸射频同轴连接器方面的一些努力，该连接器不涉及任何电气重要部分的金属对金属接触，即“非接触连接器”。介绍了同轴非接触连接器的新型设计和理论分析。

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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Thirteenth National Radio Science Conference. NRSC '96

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