- Title Pages
- [UNTITLED]
- Previous sessions
- Preface
- Illustration
- List of participants
- 1 Real-time feedback control of quantum optical input-output systems
- 2 Quantum noise and quantum measurement
- 3 Circuit QED: superconducting qubits coupled to microwave photons
- 4 Quantum logic gates in superconducting qubits
- 5 Exploring quantum matter with ultracold atoms
- 6 Readout of superconducting qubits
- 7 Quantum error correction
- 8 Quantum optomechanics
- 9 Micromechanics and superconducting circuits
- 10 Two-electron spin qubits in GaAs: control and dephasing due to nuclear spins
- 11 Exploring the quantum world with photons trapped in cavities and Rydberg atoms
- 12 SQUID amplifiers
- 13 Quantum information science: experimental implementation with trapped ions
- 14 An introduction to laser cooling optomechanical systems
- 15 Tomography schemes for characterizing itinerant microwave photon fields
- 16 Using a “frictionless” pendulum for quantum measurement
- 17 Quantum Bayesian approach to circuit QED measurement
- 18 Superconducting quantum circuits: artificial atoms coupled to 1D modes
- 19 A superconducting artificial atom with two internal degrees of freedom
Tomography schemes for characterizing itinerant microwave photon fields
Tomography schemes for characterizing itinerant microwave photon fields
- Chapter:
- (p.513) 15 Tomography schemes for characterizing itinerant microwave photon fields
- Source:
- Quantum Machines: Measurement and Control of Engineered Quantum Systems
- Author(s):
C. Eichler
D. Bozyigit
C. Lang
L. Steffen
J. Fink
A. Wallraff
- Publisher:
- Oxford University Press
This chapter illustrates the analysis of propagating microwave signals by splitters and amplifiers and shows that one can recover enough information to reconstruct the Wigner function of a microwave quantum field emitted by a qubit.
Keywords: microwave signal, splitter, amplifier, Wigner function, qubit
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- Title Pages
- [UNTITLED]
- Previous sessions
- Preface
- Illustration
- List of participants
- 1 Real-time feedback control of quantum optical input-output systems
- 2 Quantum noise and quantum measurement
- 3 Circuit QED: superconducting qubits coupled to microwave photons
- 4 Quantum logic gates in superconducting qubits
- 5 Exploring quantum matter with ultracold atoms
- 6 Readout of superconducting qubits
- 7 Quantum error correction
- 8 Quantum optomechanics
- 9 Micromechanics and superconducting circuits
- 10 Two-electron spin qubits in GaAs: control and dephasing due to nuclear spins
- 11 Exploring the quantum world with photons trapped in cavities and Rydberg atoms
- 12 SQUID amplifiers
- 13 Quantum information science: experimental implementation with trapped ions
- 14 An introduction to laser cooling optomechanical systems
- 15 Tomography schemes for characterizing itinerant microwave photon fields
- 16 Using a “frictionless” pendulum for quantum measurement
- 17 Quantum Bayesian approach to circuit QED measurement
- 18 Superconducting quantum circuits: artificial atoms coupled to 1D modes
- 19 A superconducting artificial atom with two internal degrees of freedom
