Superconducting digital Pulse-Conserving Logic (PCL) and Josephson SRAM (JSRAM) memory together enable scalable circuits with energy efficiency 100x beyond leading-node CMOS. Circuit designs support high throughput and low latency when implemented in an advanced fabrication stack with high-critical-current-density Josephson junctions of 1000μA/μm2. Pulse-conserving logic produces one single-flux-quantum output for each input, and includes a three-input, three-output gate producing logical or3, majority3 and and3. Gate macros using dual-rail data encoding eliminate inversion latency and produce efficient implementations of all standard logic functions. A full adder using 70 Josephson junctions has a carry-out latency of 5ps corresponding to an effective 12 levels of logic at 30 GHz. JSRAM (Josephson SRAM) memory uses single-flux-quantum signals throughout an active array to achieve throughput at the same clock rate as the logic. The unit cell has eight Josephson junctions, signal propagation latency of 1ps, and a footprint of 2μm2. Projected density of JSRAM is 4 MB/cm2, and computational density of pulse-conserving logic is on par with leading node CMOS accounting for power densities and clock rates.
@article{arxiv.2303.16801,
title = {Superconducting Pulse Conserving Logic and Josephson-SRAM},
author = {Quentin Herr and Trent Josephsen and Anna Herr},
journal= {arXiv preprint arXiv:2303.16801},
year = {2023}
}