Development of RFSoC-based direct sampling highly multiplexed microwave SQUID readout for future CMB and submillimeter surveys

Chao Liu, Zeeshan Ahmed, Shawn W. Henderson, Ryan Herbst, Larry Ruckman, Thomas Satterthwaite
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Abstract

The SLAC Microresonator Radio Frequency (SMuRF) electronics is being deployed as the readout for the Cosmic Microwave Background (CMB) telescopes of the Simons Observatory (SO). A Radio Frequency System-on-Chip (RFSoC) based readout of microwave frequency resonator based cryogenic sensors is under development at SLAC as an upgrade path for SMuRF with simplified RF hardware, a more compact footprint, and lower total power consumption. The high-speed integrated data converters and digital data path in RFSoC enable direct RF sampling without analog up and down conversion for RF frequencies up to 6 GHz. A comprehensive optimization and characterization study has been performed for direct RF sampling for microwave SQUID multiplexers, which covers noise level, RF dynamic range, and linearity using a prototype implementation. The SMuRF firmware, including the implementation of closed-loop tone tracking, has been ported to the RFSoC platform and interfaced with the quadrature mixers for digital up and down conversion in the data converter data path to realize a full microwave SQUID multiplexer readout. In this paper, a selection of the performance characterization results of direct RF sampling for microwave SQUID multiplexer readout will be summarized and compared with science-driven requirements. Preliminary results demonstrating the read out of cryogenic sensors using the prototype system will also be presented here. We anticipate our new RFSoC-based SMuRF system will be an enabling readout for on-going and future experiments in astronomy and cosmology, which rely on large arrays of cryogenic sensors to achieve their science goals.
为未来的 CMB 和亚毫米波测量开发基于 RFSoC 的直接采样高复用微波 SQUID 读取器
西蒙斯天文台(Simons Observatory,SO)的宇宙微波背景(CMB)望远镜正在使用 SLAC 微谐振器射频(SMuRF)电子设备作为读出设备。SLAC正在开发一种基于射频片上系统(RFSoC)的微波频率谐振器低温传感器读出器,作为SMuRF的升级途径,它具有简化的射频硬件、更紧凑的尺寸和更低的总功耗。RFSoC 中的高速集成数据转换器和数字数据路径可实现直接射频采样,无需进行模拟上下转换,射频频率可达 6 GHz。针对微波 SQUID 多路复用器的直接射频采样进行了全面的优化和特性研究,包括使用原型实现的噪声水平、射频动态范围和线性度。SMuRF 固件(包括闭环音调跟踪的实现)已导入 RFSoC 平台,并与正交混频器连接,用于数据转换器数据路径中的数字上下转换,以实现完整的微波 SQUID 多路复用器读出。本文将总结用于微波 SQUID 多路复用器读出的直接射频采样的部分性能表征结果,并与科学驱动的要求进行比较。此外,还将介绍使用原型系统读出低温传感器的初步结果。我们预计,我们基于 RFSoC 的新型 SMuRF 系统将成为天文学和宇宙学领域正在进行的和未来实验的有利读出设备,这些实验依赖大型低温传感器阵列来实现其科学目标。
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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