Digital controlling of superconducting current steering switches

Author

Brandel, Oliver ; Kunert, Juergen ; May, Torsten ; Ortlepp, Thomas ; Toepfer, Hannes ; Meyer, Hans-Georg

Author_Institution

Dept. of Quantum Detection, Leibniz Inst. of Photonic Technol., Jena, Germany

fYear

2014

fDate

7-9 July 2014

Firstpage

37

Lastpage

40

Abstract

Large arrays of superconducting radiation sensors require a multiplexed readout. One implementation of the promising code division multiplexing technique uses current steering switches (CSSs) based on superconducting quantum interference devices (SQUIDs). We pursue the concept of utilizing rapid single flux quantum (RSFQ) electronics to control these switches, where each SQUID of a CSS is inductively coupled to the storing loop of a delay flip-flop. The internal state of this digital logic element is represented by the presence of a magnetic flux quantum, which is destined to control the CSS.

Keywords

SQUIDs; code division multiplexing; delay circuits; digital control; electric current control; flip-flops; magnetic flux; readout electronics; sensor arrays; superconducting arrays; superconducting switches; CSS; RSFQ electronics; SQUID; code division multiplexing technique; delay flip-flop loop; digital control; digital logic element; magnetic flux quantum; multiplexed readout; rapid single flux quantum electronics; superconducting current steering switch; superconducting quantum interference device; superconducting radiation sensor array; Cascading style sheets; Control systems; Critical current density (superconductivity); Magnetic tunneling; Multiplexing; SQUIDs; Superconducting integrated circuits; Sensor readout; code division multiplexing; superconducting integrated circuits;

fLanguage

English

Publisher

ieee

Conference_Titel

Low Temperature Electronics (WOLTE), 2014 11th International Workshop on

Conference_Location

Grenoble

Type

conf

DOI

10.1109/WOLTE.2014.6881020

Filename

6881020