Programmable flux DACs in a Quantum Annealing Processor; Bulletin of the American Physical Society; Vol. 59, № 1

Programmable flux DACs in a Quantum Annealing Processor; Bulletin of the American Physical Society; Vol. 59, № 1

Detaylı Bibliyografya
Parent link:Bulletin of the American Physical Society.— , 2014
Vol. 59, № 1.— 2014.— Abstract: D35.00013
Diğer Yazarlar: Emile M. Hoskinson, Fabio Altomare, Andrew J. Berkley, Paul Bunyk, Richard Harris, Mark W. Johnson, Trevor M. Lanting, Elena Tolkacheva, Ilya Perminov, Uchaykin (Uchaikin) S. V. Sergey Victorovich, Jed D. Whittaker
Özet:Programming the D-Wave Two processor to solve a given problem involves adjustment of thousands of independent flux biases. This is accomplished with an array of 4480 on-chip digital-to-analog converters (DACs), addressed using 56 external lines. Each DAC comprises a superconducting loop and control circuitry that allows injection of a deterministic number of flux quanta, up to a maximum value determined by the device parameters and the addressing scheme. In-depth characterization is performed to determine DAC transfer-functions and the addressing levels needed for fast and reliable programming. In contrast with traditional single-flux-quanta (SFQ) circuitry, zero static power during programming is dissipated on-chip, allowing efficient operation at mK temperatures.
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Dil:İngilizce
Baskı/Yayın Bilgisi: 2014
Konular:
труды учёных ТПУ
Materyal Türü: Kitap Bölümü
KOHA link:https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=600818
Diğer Bilgiler
Özet:Programming the D-Wave Two processor to solve a given problem involves adjustment of thousands of independent flux biases. This is accomplished with an array of 4480 on-chip digital-to-analog converters (DACs), addressed using 56 external lines. Each DAC comprises a superconducting loop and control circuitry that allows injection of a deterministic number of flux quanta, up to a maximum value determined by the device parameters and the addressing scheme. In-depth characterization is performed to determine DAC transfer-functions and the addressing levels needed for fast and reliable programming. In contrast with traditional single-flux-quanta (SFQ) circuitry, zero static power during programming is dissipated on-chip, allowing efficient operation at mK temperatures.
В фонде НТБ ТПУ отсутствует

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