Multiplexed Readout for 1000-Pixel Arrays of Microwave Kinetic Inductance Detectors

Journal article (2016)

Authors

Jan van Rantwijk SRON Netherlands Institute for Space Research

Martin Grim SRON Netherlands Institute for Space Research

DLF van Loon SRON Netherlands Institute for Space Research

S. Yates SRON Netherlands Institute for Space Research

AM Baryshev SRON Netherlands Institute for Space Research

J.J.A. Baselmans SRON Netherlands Institute for Space Research, Tera-Hertz Sensing -

Research Group

Tera-Hertz Sensing () (TU Delft)

Kinetic inductance detectors Frequency division multiplexing Microwave superconductivity Design of microwave components for astrophysic applications Design of microwave devices and circuits Heterodyne and direct detector instruments

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http://resolver.tudelft.nl/uuid:4ce4904e-2f07-493e-b22f-b2e05faa52c0

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Published Date

01-04-2016

Language

English

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Faculty

Electrical Engineering, Mathematics and Computer Science

Department

Microelectronics

Research Group

Tera-Hertz Sensing

Abstract

Microwave kinetic inductance detectors (MKIDs) are the most attractive radiation detectors for far-infrared and sub-mm astronomy. They combine ultimate sensitivity with the possibility to create very large detector arrays, in excess of 10000 pixels. This is possible by reading-out the arrays using RF frequency division multiplexing, which allows multiplexing ratios in excess of 1000 pixels per readout line. We describe a novel readout system for large arrays of MKIDs, operating in a 2-GHz band in the 4-8-GHz range. The readout, which is a combination of a digital frontand back-end and an analog upconverter and downconverter system, can read out up to 4000 detectors simultaneously with 1-kHz data rate. The system achieves a readout noise power spectral density of -98 dBc/Hz while reading 1000 carriers simultaneously, which scales linear with the number of carriers. We demonstrate that 4000 stateof-the-art aluminium-NbTiN MKIDs can be read out without deteriorating their intrinsic performance.