Title :
Experimental characterization of bit error rate and pulse jitter in RSFQ circuits
Author :
Bunyk, P. ; Zinoviev, D.
Author_Institution :
Dept. of Phys. & Astron., State Univ. of New York, Stony Brook, NY, USA
fDate :
3/1/2001 12:00:00 AM
Abstract :
Rapid Single Flux Quantum (RSFQ) logic is well-known for its ultra-high switching speed and extremely low power consumption. In this paper, we present two original experiments to demonstrate that it´s also a reliable technology and its reliability is sufficient even for such a large-scale system as a proposed petaflops-scale HTMT computer. We have measured the bit error rate (BER) for a circular register of inverters representing a critical path of a 64-bit integer adder, and timing jitter in a 200 Josephson junction (JJ) long transmission line, imitating a branch of a clock distribution tree, both being important and representative building blocks of the HTMT computer. For the adder critical path we have demonstrated the highest clock frequency of 17 GHz, latency of 860 ps and BER of 10-19 for 3.5 μm technology of HYPRES, Inc. The value of timing jitter was 200 fs per JJ for 1.5 μm technology of TRW, Inc. These figures are in good agreement with our simulations
Keywords :
adders; clocks; logic gates; superconducting logic circuits; superconducting transmission lines; timing jitter; 1.5 micron; 17 GHz; 3.5 micron; 64 bit; HTMT computer; Josephson junction long transmission line; RSFQ logic circuit; bit error rate; carry look-ahead adder; circular register; clock distribution tree branch; critical path; inverter; latency; pulse jitter; timing jitter; Bit error rate; Clocks; Energy consumption; Inverters; Josephson junctions; Large-scale systems; Power system reliability; Registers; Timing jitter; Transmission line measurements;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
