Cell-based design methodology for BDD RSFQ logic circuits: tolerance of basic cells to circuit parameter variations

Abstract

We have proposed a cell-based design approach based on a binary decision diagram (BDD) for the design of rapid single flux quantum (RSFQ) logic circuits. In this design approach, any logic function can be implemented by simply embedding the limited number of basic cells. We have constructed a BDD RSFQ cell library and prepared a top-down CAD environment. In this study, we investigated the tolerance of the BDD RSFQ basic cells to the circuit parameter variations. It was found that theoretical and measured dc bias margins of the basic cells agree well if we assume appropriate parameter variations due to the fabrication process. The dependence of the dc bias margin of the circuits on the circuit size was also examined, where we have implemented a 2-bit multiplexer, a 4-bit data-driven self-timed shift register and a 1-bit ALU. The low-speed test results reveal that dc bias margin of the circuits containing several hundreds of Josephson junctions is about ±15%, whereas theoretical dc bias margin is about ±33%.This paper was presented at the 8th International Superconductive Electronics Conference, Osaka, Japan, 19–22 June 2001.