2019
DOI: 10.1038/s41598-019-46595-w
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Adiabatic Quantum-Flux-Parametron: Towards Building Extremely Energy-Efficient Circuits and Systems

Abstract: Adiabatic Quantum-Flux-Parametron (AQFP) logic is an adiabatic superconductor logic family that has been proposed as a future technology towards building extremely energy-efficient computing systems. In AQFP logic, dynamic energy dissipation can be drastically reduced due to the adiabatic switching operations using AC excitation currents, which serve as both clock signals and power supplies. As a result, AQFP could overcome the power/energy dissipation limitation in conventional superconductor logic families s… Show more

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Cited by 37 publications
(11 citation statements)
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“…However, given that superconducting platforms have no dissipation in their interconnects in their DC state, we believe that it is reasonable to project in such a way. We have also assumed that the constant applied bias current will not significantly affect the overall power consumption, based on previously proposed superconducting architectures that use a current dividing network made of inductors rather than resistors to eliminate the majority of dissipation from static biasing, as has been suggested for single flux quantum electronics (Mukhanov, 2011). In doing so, it is apparent that the nanowire neuron can be a highly competitive technology from a power and speed perspective, and that operation at cryogenic temperatures does not pose a serious disadvantage to its overall performance.…”
Section: The Synapsementioning
confidence: 99%
“…However, given that superconducting platforms have no dissipation in their interconnects in their DC state, we believe that it is reasonable to project in such a way. We have also assumed that the constant applied bias current will not significantly affect the overall power consumption, based on previously proposed superconducting architectures that use a current dividing network made of inductors rather than resistors to eliminate the majority of dissipation from static biasing, as has been suggested for single flux quantum electronics (Mukhanov, 2011). In doing so, it is apparent that the nanowire neuron can be a highly competitive technology from a power and speed perspective, and that operation at cryogenic temperatures does not pose a serious disadvantage to its overall performance.…”
Section: The Synapsementioning
confidence: 99%
“…J OSEPHSON junction [1] (JJ)-based superconducting circuits [2], [3] are attracting attention as an alternative technology to semiconductor integrated circuits because of its high-speed operation and superior energy efficiency [4], [5]. To date, the operation of large-scale superconducting digital circuits has been applied as information processing circuits [6], [7], [8].…”
Section: Introductionmentioning
confidence: 99%
“…Superconductor electronics have the potential to provide a high-performance, energy-efficient computing platform to power the present era of 'internet of things', big data, and social media [1][2][3]. Several energy-efficient superconductor logic families exist to provide such a platform, including energy-efficient RSFQ logic [4], energy-efficient SFQ logic [5], reciprocal quantum logic (RQL) [6], LR-biased RSFQ logic [7], and low voltage RSFQ (LV-RSFQ) logic [8].…”
Section: Introductionmentioning
confidence: 99%
“…But as with any new technology, one must consider additional overhead when it comes to building systems beyond simple logic gates. A design study on AQFP logic was conducted in [3]. It synthesized a set of benchmark circuits and performed a data-dependent energy analysis while taking into account the additional overhead of buffering data to ensure phase-to-phase propagation and synchronization of signals.…”
Section: Introductionmentioning
confidence: 99%