Dynamics of dispersive single-qubit readout in circuit quantum electrodynamics

R. Bianchetti; S. Filipp; M. Baur; J. M. Fink; M. Göppl; P. J. Leek; L. Steffen; A. Blais; A. Wallraff

doi:10.1103/PhysRevA.80.043840

Dynamics of dispersive single-qubit readout in circuit quantum electrodynamics

R. Bianchetti, S. Filipp, M. Baur, J. M. Fink, M. Göppl, P. J. Leek, L. Steffen, A. Blais, A. Wallraff

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

67 Scopus citations

Abstract

The quantum state of a superconducting qubit nonresonantly coupled to a transmission line resonator can be determined by measuring the quadrature amplitudes of an electromagnetic field transmitted through the resonator. We present experiments in which we analyze in detail the dynamics of the transmitted field as a function of the measurement frequency for both weak continuous and pulsed measurements. We find excellent agreement between our data and calculations based on a set of Bloch-type differential equations for the cavity field derived from the dispersive Jaynes-Cummings Hamiltonian including dissipation. We show that the measured system response can be used to construct a measurement operator from which the qubit population can be inferred accurately. Such a measurement operator can be used in tomographic methods to reconstruct single and multiqubit states in ensemble-averaged measurements.

Original language	English
Article number	043840
Journal	Physical Review A
Volume	80
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevA.80.043840
State	Published - 30 Oct 2009
Externally published	Yes

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title = "Dynamics of dispersive single-qubit readout in circuit quantum electrodynamics",

abstract = "The quantum state of a superconducting qubit nonresonantly coupled to a transmission line resonator can be determined by measuring the quadrature amplitudes of an electromagnetic field transmitted through the resonator. We present experiments in which we analyze in detail the dynamics of the transmitted field as a function of the measurement frequency for both weak continuous and pulsed measurements. We find excellent agreement between our data and calculations based on a set of Bloch-type differential equations for the cavity field derived from the dispersive Jaynes-Cummings Hamiltonian including dissipation. We show that the measured system response can be used to construct a measurement operator from which the qubit population can be inferred accurately. Such a measurement operator can be used in tomographic methods to reconstruct single and multiqubit states in ensemble-averaged measurements.",

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T1 - Dynamics of dispersive single-qubit readout in circuit quantum electrodynamics

AU - Bianchetti, R.

AU - Filipp, S.

AU - Baur, M.

AU - Fink, J. M.

AU - Göppl, M.

AU - Leek, P. J.

AU - Steffen, L.

AU - Blais, A.

AU - Wallraff, A.

PY - 2009/10/30

Y1 - 2009/10/30

N2 - The quantum state of a superconducting qubit nonresonantly coupled to a transmission line resonator can be determined by measuring the quadrature amplitudes of an electromagnetic field transmitted through the resonator. We present experiments in which we analyze in detail the dynamics of the transmitted field as a function of the measurement frequency for both weak continuous and pulsed measurements. We find excellent agreement between our data and calculations based on a set of Bloch-type differential equations for the cavity field derived from the dispersive Jaynes-Cummings Hamiltonian including dissipation. We show that the measured system response can be used to construct a measurement operator from which the qubit population can be inferred accurately. Such a measurement operator can be used in tomographic methods to reconstruct single and multiqubit states in ensemble-averaged measurements.

AB - The quantum state of a superconducting qubit nonresonantly coupled to a transmission line resonator can be determined by measuring the quadrature amplitudes of an electromagnetic field transmitted through the resonator. We present experiments in which we analyze in detail the dynamics of the transmitted field as a function of the measurement frequency for both weak continuous and pulsed measurements. We find excellent agreement between our data and calculations based on a set of Bloch-type differential equations for the cavity field derived from the dispersive Jaynes-Cummings Hamiltonian including dissipation. We show that the measured system response can be used to construct a measurement operator from which the qubit population can be inferred accurately. Such a measurement operator can be used in tomographic methods to reconstruct single and multiqubit states in ensemble-averaged measurements.

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Dynamics of dispersive single-qubit readout in circuit quantum electrodynamics

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