A Cryogenic SiGe Low Noise Amplifier Optimized for Phased Array Feeds

TL;DR

This paper presents a cryogenic SiGe low noise amplifier designed for phased array feeds in radio astronomy, emphasizing repeatability, low noise, and ease of manufacturing for various antenna types.

Contribution

It introduces a novel LNA design optimized for cryogenic operation with features like unpackaged transistors and off-the-shelf components, applicable across different array feed configurations.

Findings

Average in-band gain of 38 dB

Average noise temperature of 4.85 K

Design features applicable to various antenna types

Abstract

The growing number of phased array feeds (PAF) being built for radio astronomy demonstrates an increasing need for low noise amplifiers (LNA) that are designed for repeatability, low noise, and ease of manufacture. Specific design features which help to achieve these goals include the use of unpackaged transistors (for cryogenic operation), single-polarity biasing, straight plug-in RF interfaces to facilitate installation and re-work, and the use of off-the shelf components. The focal L-band array for the Green Bank Telescope (FLAG) is a cooperative effort by Brigham Young University (BYU) and the National Radio Astronomy Observatory (NRAO) using warm dipole antennae and cryogenic Silicon Germanium Heterojunction Bipolar Transistor (SiGe HBT) LNAs. These LNAs have an in band gain average of 38 dB and 4.85 Kelvin average noise temperature. Although the FLAG instrument was the driving instrument behind this development, most of the key features of the design and the advantages they offer apply broadly to other array feeds, including independent-beam and phased, and for many antenna types such as horn, dipole, Vivaldi, connected-bowtie, etc. This paper will focus on the unique requirements array feeds have for low noise amplifiers and how amplifier manufacturing can accommodate these needs.