Design of all-dc-powered high-speed single flux quantum random access memory based on a pipeline structure for memory cell arrays

We designed a superconducting random access memory ( RAM) in which all component circuits can be operated with dc-bias currents. A dc-powered superconducting loop driver and a dc-powered sense circuit are effectively combined with single flux quantum (SFQ) circuits. We proposed a pipeline structure for the memory cell array composed of the dc-powered loop drivers, the dc-powered sense circuits, passive transmission lines (PTLs), and SFQ gates. This pipeline structure enables a clock operation of 10 GHz even in a large-scale RAM. An effective device structure for the RAM based on a planarized multi-layer device structure was proposed. A dc-power layer and two PTL layers were placed under the ground plane. This structure is indispensable to create the pipeline structure using PTLs. The large inductance formed in the power layer enables low power dissipation of the RAM. We found from the estimations that 10 GHz clock operation with extremely low power dissipation can be achieved even in a large-scale RAM of 1 Mbit.