System design for large-scale ion trap quantum information processor

J. Kim; S. Pau; Z. Ma; H. R. McLellan; J. V. Gates; A. Kornblit; R. E. Slusher; R. M. Jopson; I. Kang; M. Dinu

System design for large-scale ion trap quantum information processor

J. Kim
, S. Pau
, Z. Ma
, H. R. McLellan
, J. V. Gates
, A. Kornblit
, R. E. Slusher
, R. M. Jopson
, I. Kang
, M. Dinu

Research output: Contribution to journal › Article › peer-review

Abstract

We present a detailed system design and available technology choices for building a large scale (> 100 qubits) ion trap quantum information processor (QIP). The system design is based on technologies that are within reach today, and utilizes single-instruction-on-multiple-data (SIMD) principles to re-use resources that cannot be duplicated easily. The system engineering principles adopted highlight various design tradeoffs in the QIP design and serve as a guideline to find design spaces for a much larger QIP.

Original language	English (US)
Pages (from-to)	515-537
Number of pages	23
Journal	Quantum Information and Computation
Volume	5
Issue number	7
State	Published - Nov 2005
Externally published	Yes

ASJC Scopus subject areas

Theoretical Computer Science
Statistical and Nonlinear Physics
Nuclear and High Energy Physics
Mathematical Physics
General Physics and Astronomy
Computational Theory and Mathematics

Cite this

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title = "System design for large-scale ion trap quantum information processor",

abstract = "We present a detailed system design and available technology choices for building a large scale (> 100 qubits) ion trap quantum information processor (QIP). The system design is based on technologies that are within reach today, and utilizes single-instruction-on-multiple-data (SIMD) principles to re-use resources that cannot be duplicated easily. The system engineering principles adopted highlight various design tradeoffs in the QIP design and serve as a guideline to find design spaces for a much larger QIP.",

author = "J. Kim and S. Pau and Z. Ma and McLellan, \{H. R.\} and Gates, \{J. V.\} and A. Kornblit and Slusher, \{R. E.\} and Jopson, \{R. M.\} and I. Kang and M. Dinu",

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AU - Kim, J.

AU - Pau, S.

AU - Ma, Z.

AU - McLellan, H. R.

AU - Gates, J. V.

AU - Kornblit, A.

AU - Slusher, R. E.

AU - Jopson, R. M.

AU - Kang, I.

AU - Dinu, M.

PY - 2005/11

Y1 - 2005/11

N2 - We present a detailed system design and available technology choices for building a large scale (> 100 qubits) ion trap quantum information processor (QIP). The system design is based on technologies that are within reach today, and utilizes single-instruction-on-multiple-data (SIMD) principles to re-use resources that cannot be duplicated easily. The system engineering principles adopted highlight various design tradeoffs in the QIP design and serve as a guideline to find design spaces for a much larger QIP.

AB - We present a detailed system design and available technology choices for building a large scale (> 100 qubits) ion trap quantum information processor (QIP). The system design is based on technologies that are within reach today, and utilizes single-instruction-on-multiple-data (SIMD) principles to re-use resources that cannot be duplicated easily. The system engineering principles adopted highlight various design tradeoffs in the QIP design and serve as a guideline to find design spaces for a much larger QIP.

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UR - https://www.scopus.com/pages/publications/29844441422#tab=citedBy

M3 - Article

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ER -

System design for large-scale ion trap quantum information processor

Abstract

ASJC Scopus subject areas

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