Title :
Digital SQUID sensor based on SFQ technique
Author :
Reich, Torsten ; Ortlepp, Thomas ; Uhlmann, F.Hermann
Author_Institution :
Univ. of Technol. Ilmenau, Germany
fDate :
6/1/2005 12:00:00 AM
Abstract :
For high sensitive measurements of small magnetic fields a Digital SQUID is superior to conventional analog SQUIDs in terms of dynamic properties, but recent realizations as single-flux-quantum (SFQ) circuit suffers from high complexity. A new kind of Digital SQUID as a full digital sensor device with the advantage of a small number of Josephson junctions and a large slew rate was developed. The circuit consists of basic SFQ cells and an internal digital feedback loop. The operation with a bidirectional clock signal ensures a decreased effort on superconducting electronics. The SFQ/dc converter and an additional voltage driver provides a processable digital output signal for hybrid systems including semiconductor electronics. The sensor circuit was simulated, optimized and fabricated in niobium technology. From investigation of dynamic properties of the circuit we expect a flux slew rate in the gigahertz range.
Keywords :
SQUID magnetometers; magnetic flux; Josephson junctions; Nb; SFQ cells; SFQ converter; SFQ technique; analog SQUIDs; analog to digital converter; bidirectional clock signal; dc converter; digital SQUID sensor; digital output signal; digital sensor device; dynamic property; flux slew rate; hybrid system; internal digital feedback loop; magnetic fields; niobium technology; semiconductor electronics; sensor circuit; single-flux-quantum circuit; superconducting electronics; voltage driver; Clocks; DC-DC power converters; Feedback circuits; Feedback loop; Josephson junctions; Magnetic circuits; Magnetic field measurement; Magnetic properties; Magnetic sensors; SQUIDs; Analog-to-digital-converter; Digital SQUID; RSFQ; SFQ/dc-converter; bidirectional clock signal;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.849808
