Title :
A New Design Approach for High-Throughput Arithmetic Circuits for Single-Flux-Quantum Microprocessors
Author :
Tanaka, Masamitsu ; Yamanashi, Yuki ; Kamiya, Yoshiaki ; Akimoto, Aya ; Irie, Naoki ; Park, Hee-Joung ; Fujimaki, Akira ; Yoshikawa, Nobuyuki ; Terai, Hirotaka ; Yorozu, Shinichi
Author_Institution :
Nagoya Univ., Nagoya
fDate :
6/1/2007 12:00:00 AM
Abstract :
We propose a new design approach for high- throughput arithmetic circuits based on state transitions using single-flux-quantum (SFQ) logic circuits. Microprocessors have several complex interconnects in datapath including loops of data, to which only one SFQ pulse is allowed to be confined, and the loops can spoil the high-throughput nature of SFQ circuits. In our new approach, we regard an arithmetic circuit with loops as a sequential logic circuit, and we use nondestructive readout gates (NDROs) as storage elements of the internal state. We can eliminate the loops and achieve high throughput by translating calculations into transitions of the state stored in the NDROs. We have implemented a bit-serial adder with the proposed approach, and demonstrated 36-GHz operations using the niobium 2.5-kA/cm2 standard process technology.
Keywords :
logic circuits; microprocessor chips; superconducting logic circuits; SFQ logic circuits; bit-serial adder; complex interconnects; data loops; frequency 36 GHz; high-throughput arithmetic circuits; niobium standard process technology; nondestructive readout gates; single-flux-quantum microprocessors; storage elements; Adders; Arithmetic; Integrated circuit interconnections; Josephson junctions; Logic circuits; Microprocessors; Niobium; Pulse circuits; Throughput; Wiring; Arithmetic circuits; high throughput; microprocessor; single flux quantum (SFQ) logic;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2007.898714
