Litcius/Paper detail

Design Methodology for Distributed Large-Scale ERSFQ Bias Networks

Gleb Krylov, Eby G. Friedman

2020IEEE Transactions on Very Large Scale Integration (VLSI) Systems55 citationsDOI

Abstract

Rapid single-flux quantum (RSFQ) circuits have recently attracted considerable attention as a promising cryogenic beyond CMOS technology for exascale computing. Energy-efficient RSFQ (ERSFQ) is an energy-efficient, inductive bias scheme for RSFQ circuits, where the power dissipation is drastically lowered by eliminating the bias resistors, while the cell library remains unchanged. An ERSFQ bias scheme requires the introduction of multiple circuit elements-current limiting Josephson junctions, bias inductors, and feeding Josephson transmission lines (FJTLs). In this article, parameter guidelines and design techniques for ERSFQ circuits are presented. The proposed guidelines enable more robust circuits resistant to severe variations in supplied bias currents. Trends are considered, and advantageous tradeoffs are discussed for the different components within a bias network. The guidelines provide a means to decrease the size of an FJTL and, thereby, reduce the physical area, power dissipation, and overall bias currents, supporting further increases in circuit complexity. A distributed approach to ERSFQ FJTL is also presented to simplify placement and minimize the effects of the parasitic inductance of the bias lines. This methodology and related circuit techniques are applicable to automating the synthesis of bias networks to enable large-scale ERSFQ circuits.

Topics & Concepts

Rapid single flux quantumElectronic circuitDissipationElectronic engineeringBiasingCMOSComputer scienceJosephson effectElectric power transmissionResistorIntegrated circuitElectrical engineeringPhysicsEngineeringSuperconductivityVoltageQuantum mechanicsThermodynamicsPhysics of Superconductivity and MagnetismQuantum and electron transport phenomenaSemiconductor Quantum Structures and Devices