Title :
RSFQ multiplexer and demultiplexer
Author :
Zheng, L. ; Yoshikawa, N. ; Deng, J. ; Meng, X. ; Whiteley, S. ; Van Duzer, T.
Author_Institution :
Electron. Res. Lab., California Univ., Berkeley, CA, USA
fDate :
6/1/1999 12:00:00 AM
Abstract :
An 1:8 RSFQ demultiplexer (DEMUX) and an 8:1 RSFQ multiplexer (MUX) were designed, simulated and optimized to operate at about 20 GHz. Both the inputs and outputs of the DEMUX are complementary dual-rail signals. The basic 2-bit DEMUX module is a self-clocked dual-rail T flip-flop. This DEMUX has a simpler structure than an earlier version of a data-driven-self-timed (DDST) DEMUX developed in our laboratory; however its simulated dc bias margin is (-20%, +20%), which is lower than the more complex device (-29%, +29%). The MUX takes lower data rate single-rail inputs and combines them sequentially into a single output. The complementary output is recovered from the output itself to facilitate interfacing to other dual-rail circuits on chip. The calculated dc bias margin is (-30 %, +28%). Circuit functionality is verified for the 2-bit MUX and the 2-bit DEMUX at low speed. An on-chip high-speed test system is designed to evaluate operation of the MUX and DEMUX at 20 GHz. The circuits are fabricated using a 1 kA/cm/sup 2/ niobium process at both UCB and HYPRES.
Keywords :
demultiplexing equipment; flip-flops; multiplexing equipment; superconducting integrated circuits; 2 bit; 20 GHz; Nb; RSFQ demultiplexer; RSFQ multiplexer; on-chip high-speed testing; self-clocked dual-rail T flip-flop; superconducting integrated circuit; Clocks; Communication switching; Flip-flops; High speed optical techniques; Integrated circuit technology; Laboratories; Multiplexing; Niobium; Optical switches; Superconductivity;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
