Thermal testing of small antennas in multi-probe spherical near-field systems

2017 Antenna Measurement Techniques Association Symposium (AMTA) Pub Date : 2017-10-01 DOI:10.23919/AMTAP.2017.8123715

A. Giacomini, R. Morbidini, L. Foged, J. Acree, J. Estrada, E. Szpindor, P. Iversen

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引用次数: 3

Abstract

Temperature changes cause thermal expansion of antenna materials and will have an important impact on antenna performances. In some applications, it is sufficient to calculate the antenna deformation by mechanical analysis and determine the RF impact by EM analysis tools. However, if the environmental conditions of the final antenna are stringent and considered critical as in the case of military and civil applications like space and aeronautics, the thermal performance of the antenna must be determined by experiment [1]-[2]. Based on the preliminary results discussed in [3], this paper present a simple and effective method for thermal testing of antennas in a spherical near field range based on multi probe technology [4]-[9]. The antenna is maintained inside an RF transparent thermally insulated container including the local heating and cooling equipment. The fast testing provided by the multiprobe system allows one to measure the temperature dependence of the antenna at several different temperatures within the investigation range. The method will be illustrated for the cold measurement case with temperatures below −100°C but the extension to the full cold to hot temperature range is trivial.

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多探头球面近场系统小天线热测试

温度变化会引起天线材料的热膨胀，对天线性能产生重要影响。在某些应用中，通过力学分析计算天线变形，通过EM分析工具确定射频影响就足够了。然而，如果最终天线的环境条件是严格的，并且被认为是关键的，如在军事和民用应用的情况下，如航天和航空，天线的热性能必须通过实验来确定[1]-[2]。在文献[3]初步结果的基础上，本文提出了一种基于多探头技术的球面近场范围内天线热测试的简单有效方法[4]-[9]。天线保持在射频透明隔热容器内，包括局部加热和冷却设备。多探头系统提供的快速测试允许在研究范围内的几个不同温度下测量天线的温度依赖性。该方法将在温度低于- 100°C的冷测量情况下进行说明，但扩展到整个冷到热温度范围是微不足道的。

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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2017 Antenna Measurement Techniques Association Symposium (AMTA)

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