Efficient cavity control with SNAP gates
ORAL
Abstract
Microwave cavities coupled to superconducting qubits have been demonstrated to be a promising platform for quantum information processing. A major challenge in this setup is to realize universal control over the cavity. A promising approach are selective number-dependent arbitrary phase (SNAP) gates combined with cavity displacements. Whereas it could be proven that this is a universal gate set, a central question remained open: how can a given target operation be realized efficiently with a sequence of these operations.
In this talk, we present a practical scheme to address this problem. We will compare our results to previously known techniques: for many experimentally relevant applications, we find that the sequence length can be reduced by a factor of around 10 or higher. We will also sketch the working principle of our method.
In this talk, we present a practical scheme to address this problem. We will compare our results to previously known techniques: for many experimentally relevant applications, we find that the sequence length can be reduced by a factor of around 10 or higher. We will also sketch the working principle of our method.
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Presenters
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Thomas Foesel
Max Planck Inst for Sci Light
Authors
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Thomas Foesel
Max Planck Inst for Sci Light
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Stefan Krastanov
Massachusetts Institute of Technology MIT, Massachusetts Institute of Technology
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Liang Jiang
University of Chicago, Pritzker School for Molecular Engineering, University of Chicago, Pritzker School of Molecular Engineering, University of Chicago, Yale University
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Florian Marquardt
Max Planck Inst for Sci Light, Max Planck Institute for the Science of Light