RSFQ: What we know and what we don't

Abstract

Rapid Single Flux Quantum (RSFQ) Josephson-junction technology is capable of processing digital data at sub-terahertz frequencies while dissipating almost negligible power. At the present time one can routinely simulate, optimize, design, manufacture, and test an elementary RSFQ logic/memory cell consisting of dozens of Josephson junctions. Furthermore, a number of relatively complex (few hundred to few thousand Josephson junctions) digital circuits were designed and successfully tested. Moreover we know how to implement several RSFQ systems (including analog-to-digital and digital-to-analog converters, digital SQUIDs for supersensitive magnetometry, and digital autocorrelator for radioastronomy) which would far outperform their currently available and even prospective semiconductor counterparts. In order to implement more complex RSFQ systems, including high-performance digital signal processors and general purpose computers there are a number of technical problems to solve. The issues include making full use of on-chip sub-terahertz processing in conditions when inter-chip data/clock exchange speed is bound by bandwidth of the order of a few Gbps/pin. I present the current know-how of the field, and formulate the questions that need to be solved before the RSFQ technology becomes a major workhorse of high-performance computation.