Q-band receiver system design for the Canadian DVA-2 radio telescope

Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy X Pub Date : 2020-12-13 DOI:10.1117/12.2562751

Sara Salem Hesari, D. Henke, V. Reshetov, F. Jiang, A. Seyfollahi, L. Knee, L. Baker, J. Bornemann, D. Chalmers

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引用次数: 3

Abstract

A compact front-end system is presented for a dual-linear polarization cryogenic Q-band receiver. This receiver will be used to demonstrate the high frequency performance of the Dish Verification Antenna 2 (DVA-2) composite reflector telescope between 35–50 GHz and is a technology demonstrator with possible application to the National Radio Astronomy Observatory’s Next Generation Very Large Array (ngVLA). A vacuum vessel and a two-stage Gifford-McMahon cryopump system are used for the cryogenic environment. The second stage of the cryostat is cooled to 16 K and includes a small choke ring feed horn, a low-loss noise calibration module (NCM) integrated with orthogonal mode transducer (OMT), and two cryogenically cooled mHEMT MMIC low-noise amplifiers (LNAs). Using a noise diode as the noise source on the 300 K stage inside the cryostat helps to protect the cooled components from signals outside of the cryostat, and also lessen the heat on the second stage since a noise diode normally produce a power dissipation of several hundred mW. The OMT design is an optimized version of the design used in the ALMA Band 1 cartridge with two integrated directional couplers and excellent performance. The cascaded noise analysis of the receiver shows a receiver noise temperature of 19.4 K.

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加拿大DVA-2射电望远镜q波段接收系统设计

提出了一种紧凑的双线偏振低温q波段接收机前端系统。该接收器将用于演示碟形验证天线2 (DVA-2)复合反射镜望远镜在35-50 GHz之间的高频性能，并且是可能应用于国家射电天文台下一代甚大阵列(ngVLA)的技术演示。真空容器和两级吉福德-麦克马洪低温泵系统用于低温环境。低温恒温器的第二级冷却至16 K，包括一个小扼流环馈电喇叭，一个与正交模式传感器(OMT)集成的低损耗噪声校准模块(NCM)，以及两个低温冷却的mHEMT MMIC低噪声放大器(LNAs)。在低温恒温器内部的300k级上使用噪声二极管作为噪声源有助于保护冷却组件免受低温恒温器外部信号的影响，并且还可以减少第二级的热量，因为噪声二极管通常会产生数百mW的功耗。OMT设计是ALMA Band 1中使用的设计的优化版本，具有两个集成定向耦合器，性能优异。接收机的级联噪声分析表明，接收机噪声温度为19.4 K。

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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Millimeter, Submillimeter, and Far-Infrared Detectors and Instrumentation for Astronomy X

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