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引用次数: 0
摘要
多通道多级SQUID放大器系统中的偏置布置,例如用于天文观测的过渡边缘传感器矩阵(Barrett et al., 2023)或量子科学(Hummatov et al., 2023),通常需要大量导线。这是因为需要两个或更多级联SQUID级才能在足够的带宽上获得足够大的功率增益,并且由于适度的可获得的多路复用因素,这迫使实现许多并行读出链来服务所有传感器像素。我们建议在单个芯片上的两个级联SQUID级共享一条偏置线和一条通量设定值线的安排,将两个级联级通常需要的线数减半。这些级是串联连接的,共享一个单一的电源电流,双到普通集成晶体管电路,其中许多晶体管级并联连接并共享一个单一的电源电压。我们展示了在T = 4.2 K下,使用swap Josephson结(Grönberg等人,2017)在VTT Micronova代工厂制造的概念验证放大器芯片的实验结果,临界电流密度为20 μA/(μm)2。从LIN = 29 nH的输入电感到RD < 150 Ω的输出动态电阻,器件显示出大于3 kΩ的通阻。
Two-Stage SQUID Amplifier With Bias Current Re-Use
Biasing arrangements in multi-channel multi-stage SQUID amplifier systems, such as Transition Edge Sensor matrices for astronomical observation (Barrett et al., 2023) or quantum science (Hummatov et al., 2023), typically require a large number of wires. This is due to the need for two or more cascaded SQUID stages to obtain sufficiently large power gain over a sufficient bandwidth, and due to moderate obtainable multiplexing factors, which forces implementation of many parallel readout chains to serve all the sensor pixels. We suggest an arrangement where one bias line and one flux setpoint line are shared by two cascaded SQUID stages on a single chip, halving the number of lines two cascaded stages would ordinarily require. The stages are connected in series, sharing a single supply
current
, dual to ordinary integrated transistor circuits in which many transistor stages are connected in parallel and share a single supply
voltage
. We show experimental results at
T
= 4.2 K for a proof-of-concept amplifier chip, fabricated in the VTT Micronova foundry, using SWAPS Josephson junctions (Grönberg et al., 2017) at
JC
= 20 μA/(μm)
2
critical current density. The device shows larger than 3 kΩ transresistance, when operating from
LIN
= 29 nH input inductance to
RD
< 150 Ω output dynamic resistance.
期刊介绍:
IEEE Transactions on Applied Superconductivity (TAS) contains articles on the applications of superconductivity and other relevant technology. Electronic applications include analog and digital circuits employing thin films and active devices such as Josephson junctions. Large scale applications include magnets for power applications such as motors and generators, for magnetic resonance, for accelerators, and cable applications such as power transmission.
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