High-Speed Experimental Demonstration of Adiabatic Quantum-Flux-Parametron Gates Using Quantum-Flux-Latches

Takeuchi, Naoki; Ortlepp, Thomas; Yamanashi, Yuki; Yoshikawa, Nobuyuki

doi:10.1109/tasc.2014.2311444

Cited by 7 publications

(7 citation statements)

References 11 publications

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“…It is clear that through the use of RQFP gates, detailed discussion and investigations on the energy efficiency of reversible computing will become possible. Although the energy dissipation of the RQFP gate was too small to measure in the low-speed demonstration at 100 kHz, we expect that we will be able to measure it at a higher operation frequency (~1 GHz) in future work by using high-speed interface circuits31 and the superconducting resonator-based method24. Also, in previous work24, we have confirmed that calculation results of energy dissipation well agree with experimental results using superconducting resonators.…”

Section: Discussionsupporting

confidence: 75%

Reversible logic gate using adiabatic superconducting devices

Takeuchi

Yamanashi

Yoshikawa

2014

Sci Rep

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Reversible computing has been studied since Rolf Landauer advanced the argument that has come to be known as Landauer's principle. This principle states that there is no minimum energy dissipation for logic operations in reversible computing, because it is not accompanied by reductions in information entropy. However, until now, no practical reversible logic gates have been demonstrated. One of the problems is that reversible logic gates must be built by using extremely energy-efficient logic devices. Another difficulty is that reversible logic gates must be both logically and physically reversible. Here we propose the first practical reversible logic gate using adiabatic superconducting devices and experimentally demonstrate the logical and physical reversibility of the gate. Additionally, we estimate the energy dissipation of the gate, and discuss the minimum energy dissipation required for reversible logic operations. It is expected that the results of this study will enable reversible computing to move from the theoretical stage into practical usage.

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Section: Discussionsupporting

confidence: 75%

Reversible logic gate using adiabatic superconducting devices

Takeuchi

Yamanashi

Yoshikawa

2014

Sci Rep

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“…This allows one to reduce decoherence in the considered scheme. Experimental studies have shown that ASL circuits demonstrate ultra-high (even for superconducting circuits) energy efficiency with an increase in operating frequencies up to several gigahertz [39]. A numerical study of the dynamic processes [40] in the nSQUID allowed us to select parameters for which it is possible for the picosecond control pulses with the required shape and accuracy to pass through the ASL transmission line.…”

Section: Resultsmentioning

confidence: 99%

Unipolar magnetic field pulses as an advantageous tool for ultrafast operations in superconducting Josephson “atoms”

Popolitova

Klenov

Soloviev

et al. 2019

Beilstein J. Nanotechnol.

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A theoretical approach to the consistent full quantum description of the ultrafast population transfer and magnetization reversal in superconducting meta-atoms induced by picosecond unipolar pulses of a magnetic field is developed. A promising scheme based on the regime of stimulated Raman Λ-type transitions between qubit states via upper-lying levels is suggested in order to provide ultrafast quantum operations on the picosecond time scale. The experimental realization of a circuit-on-chip for the discussed ultrafast control is presented.

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“…However, QFLs could realize AQFP circuits with totally new operation principles, such as the high-speed interface circuit [13] and the QXOR.…”

Section: Discussionmentioning

confidence: 99%

“…It should be noted that the QFL not only provides a solution to data storage in AQFP logic, but also can lead to new applications. In the previous study, we demonstrated AQFP logic circuits at 1 GHz using QFLs as high-speed interface circuits [13]. In this paper, we report a novel QFL-based XOR gate.…”

Section: Introductionmentioning

confidence: 91%

“…Fig. 3 shows the micrographs of the fabricated circuits, where the circuit parameters and layout are similar to those reported in [11], [13] with J 0 = 30 μA. To increase input currents to the QXORs for wider bias margins of I b , we placed high-I c buffer gates, whose critical currents are designed to be 100 μA, before the QXORs.…”

Section: B Experimental Demonstrationmentioning

confidence: 99%

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Experimental demonstration of quantum-flux-latch-based circuits

Takeuchi

Ortlepp

Yamanashi

et al. 2014

IEEE Trans. Appl. Supercond.

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We propose and discuss quantum-flux-latch (QFL) based circuits for adiabatic quantum-flux-parametron (AQFP) logic. The QFL-based XOR (QXOR) gate is a novel XOR gate. The circuit schematic of the QXOR is the same as that of a QFL, but QXORs operate on a different operation principle due to ac biasing. We designed and fabricated the QXOR and the half adder including a QXOR. We successfully demonstrated correct logic operations of these circuits at 4.2 K in the low-speed function test. Also, we estimated the energy dissipation of the QFL using a circuit simulator. The estimated energy dissipation was ∼0.2 aJ/cycle. Index Terms-Adiabatic logic, adiabatic quantum-fluxparametron (AQFP), low-power, quantum-flux-latch (QFL), XOR.

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High-Speed Experimental Demonstration of Adiabatic Quantum-Flux-Parametron Gates Using Quantum-Flux-Latches

Cited by 7 publications

References 11 publications

Reversible logic gate using adiabatic superconducting devices

Reversible logic gate using adiabatic superconducting devices

Unipolar magnetic field pulses as an advantageous tool for ultrafast operations in superconducting Josephson “atoms”

Experimental demonstration of quantum-flux-latch-based circuits

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