Title :
Sub-picosecond measurement of time intervals using single flux quantum electronics
Author_Institution :
Nat. Inst. of Sci. & Technol., Boulder, CO, USA
fDate :
3/1/1993 12:00:00 AM
Abstract :
A single-flux-quantum (SFQ) pulse coincidence detector based on resistively shunted nonhysteretic Josephson junctions was designed and simulated. The coincidence detector generates an SFQ pulse when the delay between the arrival of SFQ pulses at its two inputs is less than the coincidence threshold. Simulations indicate that the minimum coincidence threshold time can be as short as 400+or-200 fs, assuming Josephson junction characteristic voltages of 1 mV, overdamped dynamics, and 4.2 K operating temperatures. Circuit architectures exploiting this gate are suggested. Estimates of the effects of thermal noise on resolution are presented, indicating the potential for various time-domain measurements with subpicosecond resolution.<>
Keywords :
Josephson effect; coincidence circuits; electron device noise; superconducting junction devices; thermal noise; time measurement; 1 mV; 4.2 K; 400 fs; SFQ pulse; nonhysteretic Josephson junctions; overdamped dynamics; pulse coincidence detector; resistively shunted; single flux quantum electronics; subpicosecond resolution; thermal noise; time interval measurement; time-domain measurements; Circuit noise; Circuit simulation; Delay; Detectors; Josephson junctions; Pulse generation; Temperature; Threshold voltage; Time domain analysis; Time measurement;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
