Kazunori Nakamiya scite author profile

Kazunori Nakamiya

3Publications

9Citation Statements Received

35Citation Statements Given

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Affiliations

Yokohama National University

Publications

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Design and Implementation of a Fully Asynchronous SFQ Microprocessor: SCRAM2

Nobumori

Nishigai

Nakamiya

et al. 2007

IEEE Trans. Appl. Supercond.

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A microprocessor test vehicle was developed for the investigation of asynchronous design methodology for rapidsingle-flux-quantum (RSFQ) circuits. We have designed and implemented a fully asynchronous RSFQ microprocessor, named SCRAM2. The data-driven self-timing (DDST) architecture is used for the design of circuit blocks of the SCRAM2. In order to ensure the logical ordering between the circuit blocks, bit-serial handshaking was adopted. The performance of the handshaking system was enhanced based on the scalable-delay-insensitive (SDI) model. The SCRAM2 is an 8-bit bit-serial microprocessor with three-stage pipelining, with a basic microarchitecture similar to that of our previously designed synchronous microprocessor, CORE1. The estimated average performance of the SCRAM2 is 577 MIPS using a logic simulation. We have implemented all circuit components using the SRL 2.5 kA cm 2 Nb process and confirmed their correct operation. Several operations of the SCRAM2 have been successfully confirmed.

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Improvement of time resolution of the double-oscillator time-to-digital converter using SFQ circuits

Nakamiya

Nishigai

Yoshikawa

et al. 2007

Physica C: Superconductivity and its Applications

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We have designed, fabricated and tested a time-to-digital converter (TDC) using SFQ logic circuits. The proposed TDC consists of two sets of ring oscillators and binary counters, and a coincidence detector (CD), which detects the coincidence of the arrival of two SFQ pulses from two ring oscillators. The advantage of the proposed TDC is its simple circuit structure with wide measurement range in addition to the high resolution and the high sensitivity of the SFQ TDC compared to semiconductor TDCs. The time resolution of the proposed TDC is limited by the resolution of the CD. In order to improve the resolution, we have developed a dynamic AND (DAND) gate, which can detect two simultaneous SFQ signal inputs with high accuracy. It was demonstrated that the time resolution of the TDC using the DAND gate is improved to be ±4 ps.

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Direct measurements of propagation delay of single-flux-quantum circuits by time-to-digital converters

Nakamiya

Yoshikawa

Fujimaki

et al. 2008

IEICE Electron. Express

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Direct measurements of propagation delay of single-fluxquantum (SFQ) circuits were performed using SFQ double-oscillator time-to-digital converters. The propagation delay of several SFQ logic gates in our cell library named CONNECT were measured in picosecond resolution. Small discrepancy in the propagation delay of picosecond level was observed between measurement and circuit simulation results. The discrepancy is well explained assuming the parasitic inductance around shunt resistors of Josephson junctions. Keywords: SFQ circuits, superconducting devices, TDC, Josephson junctions, superconducting integrated circuits, propagation delay Classification: Superconductivity References

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