Naoki Tsuji

Magnetically coupled quantum-flux-latch with wide operation margins

We have been developing adiabatic quantum-flux-parametron (AQFP) circuits as an ultra-low-power superconductor logic for energy-efficient computing. In a previous study, we proposed and demonstrated a quantum-flux-latch (QFL), which is a compact and compatible latch for AQFP logic. The QFL is composed of an AQFP buffer gate and a storage loop, which are directly connected to each other. However, the operation margins were not sufficiently wide due to a trade-off between the operation margins of the storage loop and that of the buffer gate. In this present study, we propose a magnetically coupled QFL (MC-QFL), where the storage loop and the buffer gate are physically separated and magnetically coupled to each other to eliminate the trade-off in the operation margins. The simulation results showed that the critical parameter margin of the MC-QFL is twice as large as that of the previously designed QFL. For comparison, we fabricated and demonstrated both the previously designed QFL and the newly designed MC-QFL. The measurement results showed that the MC-QFL has wider operation margins compared with the previously designed QFL.

Demonstration of Signal Transmission Between Adiabatic Quantum-Flux-Parametrons and Rapid Single-Flux-Quantum Circuits Using Superconductive Microstrip Lines

We have been investigating interface circuits between rapid single-flux-quantum circuits and adiabatic quantum-flux-parametron (AQFP) circuits for use in high-speed low-power hybrid computing system. These interface circuits also enable us to use long-distance interconnections between AQFP gates. In this study, we fabricated and demonstrated AQFP circuits, including long interconnections of passive transmission lines (PTLs), in which the interface circuits were used to convert the signal currents of the AQFP gates into single-flux-quantum pulses traveling along PTLs. The length of each PTL was approximately 4.3 mm. During low-speed measurements, correct operations with wide bias margins were confirmed.