report.bib

@article{schuster2007,
  title={Resolving photon number states in a superconducting circuit},
  author={Schuster, D.I. and Houck, A.A. and Schreier, J.A. and Wallraff, A. and Gambetta, J.M. and Blais, A and Frunzio, L and Majer, J and Johnson, B and Devoret, MH and others},
  journal={Nature},
  volume={445},
  number={7127},
  pages={515--518},
  year={2007},
  publisher={Nature Publishing Group}
}



@article{schuster2005,
  title={AC Stark shift and dephasing of a superconducting qubit strongly coupled to a cavity field},
  author={Schuster, D.I. and Wallraff, A. and Blais, A. and Frunzio, L. and Huang, R.-S. and Majer, J. and Girvin, S. M. and Schoelkopf, R. J.},
  journal={Physical Review Letters},
  volume={94},
  number={12},
  pages={123602},
  year={2005},
  publisher={APS}
}


@article{dolan1977,
  title={Offset masks for lift-off photoprocessing},
  author={Dolan, G.J.},
  journal={Applied Physics Letters},
  volume={31},
  number={5},
  pages={337--339},
  year={1977},
  publisher={AIP}
}

@article{Khalil2012,
abstract = {We examine the transmission through a microwave coplanar waveguide which is coupled to a superconducting thin-film resonator. The general analytical resonance line shape is derived for both inductive and capacitive coupling with mismatched input and output transmission impedances, and it's found that for certain non-ideal conditions the line shape is asymmetric. We describe a novel method for extracting an accurate internal quality factor (Q{\_}i), the Diameter Correction Method (DCM), and compare it to the conventional method used for millikelvin resonator measurements, the $\backslash$phi$\backslash$ Rotation Method ($\backslash$phi RM). Both analytically and using simulations from a numerical linear solver we find that the $\backslash$phi RM deterministically overestimates Q{\_}i when the asymmetry of the resonance line shape is high. Both methods are also used to analyze data from asymmetric coplanar superconducting aluminum resonators and a consistent discrepancy between the two methods is observed as with the simulated results.},
archivePrefix = {arXiv},
arxivId = {1108.3117},
author = {Khalil, M. S. and Stoutimore, M. J A and Wellstood, F. C. and Osborn, K. D.},
doi = {10.1063/1.3692073},
eprint = {1108.3117},
file = {:home/gleb/Документы/Mendeley Desktop/An analysis method for asymmetric resonator transmission applied to superconducting devices - Khalil et al. - 2012.pdf:pdf},
issn = {00218979},
journal = {Journal of Applied Physics},
mendeley-groups = {Resonator materials},
number = {5},
title = {{An analysis method for asymmetric resonator transmission applied to superconducting devices}},
volume = {111},
year = {2012}
}


@article{Deng2013,
author = {Deng, C. and Otto, M. and Lupascu, A.},
doi = {10.1063/1.4817512},
eprint = {1304.4533},
issn = {00218979},
journal = {Journal of Applied Physics},
mendeley-groups = {Resonator materials},
number = {5},
pages = {1--12},
title = {{An analysis method for transmission measurements of superconducting resonators with applications to quantum-regime dielectric-loss measurements}},
volume = {114},
year = {2013}
}


@article{martinis2014,
  title={Calculation of Coupling Capacitance in Planar Electrodes},
  author={Martinis, J. M. and Barends, R. and Korotkov, A. N.},
  journal={arXiv preprint arXiv:1410.3458},
  year={2014}
}


@article{astafiev2010,
  title={Resonance fluorescence of a single artificial atom},
  author={Astafiev, O. and Zagoskin, A. M. and Abdumalikov, A. A. and Pashkin, Y. A. and Yamamoto, T. and Inomata, K. and Nakamura, Y. and Tsai, J. S.},
  journal={Science},
  volume={327},
  number={5967},
  pages={840--843},
  year={2010},
  publisher={American Association for the Advancement of Science}
}

@article{Lucero2010,
abstract = {Minimizing phase and other errors in experimental quantum gates allows higher fidelity quantum processing. To quantify and correct for phase errors in particular, we have developed a new experimental metrology --- amplified phase error (APE) pulses --- that amplifies and helps identify phase errors in general multi-level qubit architectures. In order to correct for both phase and amplitude errors specific to virtual transitions and leakage outside of the qubit manifold, we implement "half derivative" an experimental simplification of derivative reduction by adiabatic gate (DRAG) control theory. The phase errors are lowered by about a factor of five using this method to {\$}\backslashsim 1.6{\^{}}{\{}\backslashcirc{\}}{\$} per gate, and can be tuned to zero. Leakage outside the qubit manifold, to the qubit {\$}|2\backslashrangle{\$} state, is also reduced to {\$}\backslashsim 10{\^{}}{\{}-4{\}}{\$} for {\$}20\backslash{\%}{\$} faster gates.},
archivePrefix = {arXiv},
arxivId = {1007.1690},
author = {Lucero, E. and Kelly, J. and Bialczak, R. C. and Lenander, M. and Mariantoni, M. and Neeley, M. and O'Connell, A. D. and Sank, D. and Wang, H. and Weides, M. and Wenner, J. and Yamamoto, T. and Cleland, A. N. and Martinis, J. M.},
doi = {10.1103/PhysRevA.82.042339},
eprint = {1007.1690},
file = {:home/gleb/Документы/Mendeley Desktop/Reduced phase error through optimized control of a superconducting qubit - Lucero et al. - 2010.pdf:pdf},
isbn = {1050-2947},
issn = {10502947},
journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
mendeley-groups = {Papers qubits},
number = {4},
pages = {1--7},
title = {{Reduced phase error through optimized control of a superconducting qubit}},
volume = {82},
year = {2010}
}


@article{Motzoi2009,
abstract = {In realizations of quantum computing, a two-level system (qubit) is often singled out of the many levels of an anharmonic oscillator. In these cases, simple qubit control fails on short time scales because of coupling to leakage levels. We provide an easy to implement analytic formula that inhibits this leakage from any single-control analog or pixelated pulse. It is based on adding a second control that is proportional to the time-derivative of the first. For realistic parameters of superconducting qubits, this strategy reduces the error by an order of magnitude relative to the state of the art, all based on smooth and feasible pulse shapes. These results show that even weak anharmonicity is sufficient and in general not a limiting factor for implementing quantum gates.},
archivePrefix = {arXiv},
arxivId = {0901.0534},
author = {Motzoi, F. and Gambetta, J. M. and Rebentrost, P. and Wilhelm, F. K.},
doi = {10.1103/PhysRevLett.103.110501},
eprint = {0901.0534},
file = {:home/gleb/Документы/Mendeley Desktop/Simple Pulses for Elimination of Leakage in Weakly Nonlinear Qubits - Motzoi et al. - 2009.pdf:pdf},
isbn = {0031-9007},
issn = {00319007},
journal = {Physical Review Letters},
mendeley-groups = {Papers qubits},
number = {11},
pages = {1--4},
pmid = {19792356},
title = {{Simple Pulses for Elimination of Leakage in Weakly Nonlinear Qubits}},
volume = {103},
year = {2009}
}

@article{Chow2010,
abstract = {We employ simultaneous shaping of in-phase and out-of-phase resonant microwave drives to reduce single-qubit gate errors arising from the weak anharmonicity of transmon superconducting artificial atoms. To reduce the effect of higher levels present in the transmon spectrum, we apply Gaussian and derivative-of-Gaussian envelopes to the in-phase and out-of-phase quadratures, respectively, and optimize over their relative amplitude. Using randomized benchmarking, we obtain a minimum average error per gate of 0.007 +/- 0.005 using 4-ns-wide pulses, which is limited by decoherence. This simple optimization technique works for multiple transmons coupled to a single microwave resonator in a quantum bus architecture.},
archivePrefix = {arXiv},
arxivId = {1005.1279},
author = {Chow, J. M. and Dicarlo, L. and Gambetta, J. M. and Motzoi, F. and Frunzio, L. and Girvin, S. M. and Schoelkopf, R. J.},
doi = {10.1103/PhysRevA.82.040305},
eprint = {1005.1279},
file = {:home/gleb/Документы/Mendeley Desktop/Optimized driving of superconducting artificial atoms for improved single-qubit gates - Chow et al. - 2010.pdf:pdf},
isbn = {1050-2947},
issn = {10502947},
journal = {Physical Review A - Atomic, Molecular, and Optical Physics},
mendeley-groups = {Papers qubits},
number = {4},
pages = {2--5},
title = {{Optimized driving of superconducting artificial atoms for improved single-qubit gates}},
volume = {82},
year = {2010}
}


@book{faisal2013,
  title={Theory of multiphoton processes},
  author={Faisal, F. H. M.},
  year={2013},
  publisher={Springer Science \& Business Media}
}


@article{bishop2009,
  title={Nonlinear response of the vacuum Rabi resonance},
  author={Bishop, L. S. and Chow, J. M. and Koch, J. and Houck, A. A. and Devoret, M. H. and Thuneberg, E. and Girvin, S. M. and Schoelkopf, R. J.},
  journal={Nature Physics},
  volume={5},
  number={2},
  pages={105--109},
  year={2009},
  publisher={Nature Publishing Group}
}

@article{Devoret1995,
author = {Devoret, M. H.},
file = {:home/gleb/Документы/Mendeley Desktop/Quantum fluctuations in electrical circuits - Devoret - 1995.pdf:pdf},
journal = {Les Houches, Session LXIII},
title = {{Quantum fluctuations in electrical circuits}},
url = {http://www.physique.usherb.ca/tremblay/cours/PHY-731/Quantum{\_}circuit{\_}theory-1.pdf},
year = {1995}
}


@article{barends2013,
  title={Coherent Josephson qubit suitable for scalable quantum integrated circuits},
  author={Barends, R. and Kelly, J. and Megrant, A. and Sank, D. and Jeffrey, E. and Chen, Y and Yin, Y. and Chiaro, B. and Mutus, J. and Neill, C. and others},
  journal={Physical review letters},
  volume={111},
  number={8},
  pages={080502},
  year={2013},
  publisher={APS}
}


@article{paik2011,
  title={Observation of high coherence in Josephson junction qubits measured in a three-dimensional circuit QED architecture},
  author={Paik, H. and Schuster, D. and Bishop, L. S. and Kirchmair, G. and Catelani, G. and Sears, A.P. and Johnson, B. R. and Reagor, M. J. and Frunzio, L. and Glazman, L. I. and others},
  journal={Physical Review Letters},
  volume={107},
  number={24},
  pages={240501},
  year={2011},
  publisher={APS}
}




@article{wang2009,
  title={Improving the coherence time of superconducting coplanar resonators},
  author={Wang, H. and Hofheinz, M. and Wenner, J. and Ansmann, M. and Bialczak, R. C. and Lenander, M. and Lucero, E. and Neeley, M. and O’Connell, A. D. and Sank, D. and others},
  journal={Applied Physics Letters},
  volume={95},
  number={23},
  pages={233508},
  year={2009},
  publisher={AIP Publishing}
}


@article{probst2015,
  title={Efficient and robust analysis of complex scattering data under noise in microwave resonators},
  author={Probst, S. and Song, F.B. and Bushev, P. A. and Ustinov, A. V. and Weides, M.},
  journal={Review of Scientific Instruments},
  volume={86},
  number={2},
  pages={024706},
  year={2015},
  publisher={AIP Publishing}
}

@phdthesis{Sank2014,
author = {Sank, D. T.},
mendeley-groups = {Dissers},
title = {{Fast, Accurate State Measurement in Superconducting Qubits}},
year = {2014}
}

@article{Zurek2003,
abstract = {Decoherence is caused by the interaction with the environment. Environment monitors certain observables of the system, destroying interference between the pointer states corresponding to their eigenvalues. This leads to environment-induced superselection or einselection, a quantum process associated with selective loss of information. Einselected pointer states are stable. They can retain correlations with the rest of the Universe in spite of the environment. Einselection enforces classicality by imposing an effective ban on the vast majority of the Hilbert space, eliminating especially the flagrantly non-local "Schr$\backslash$"odinger cat" states. Classical structure of phase space emerges from the quantum Hilbert space in the appropriate macroscopic limit: Combination of einselection with dynamics leads to the idealizations of a point and of a classical trajectory. In measurements, einselection replaces quantum entanglement between the apparatus and the measured system with the classical correlation.},
archivePrefix = {arXiv},
arxivId = {quant-ph/0105127},
author = {Zurek, W. H.},
doi = {10.1103/RevModPhys.75.715},
eprint = {0105127},
file = {:C$\backslash$:/Users/gleb/Documents/Mendeley Desktop/Zurek - 2003 - Decoherence, einselection, and the quantum origins of the classical.pdf:pdf},
isbn = {0034-6861},
issn = {00346861},
journal = {Reviews of Modern Physics},
mendeley-groups = {Papers qubits},
number = {3},
pages = {715--775},
primaryClass = {quant-ph},
title = {{Decoherence, einselection, and the quantum origins of the classical}},
volume = {75},
year = {2003}
}


@article{Preskill,

title = {{Notes on noise}},
author={Preskill, J.},
url = {http://www.theory.caltech.edu/people/preskill/papers/decoherence_notes.pdf},
}

@article{Bylander2011,

arxivId = {1101.4707},
author = {Bylander, J. and Gustavsson, S. and Yan, F. and Yoshihara, F. and Harrabi, K. and Fitch, G. and Cory, D. G. and Nakamura, Y. and Tsai, J. S. and Oliver, W. D.},
doi = {10.1038/nphys1994},
eprint = {1101.4707},
file = {:C$\backslash$:/Users/gleb/Documents/Mendeley Desktop/nphys1994.pdf:pdf},
isbn = {1745-2473},
issn = {1745-2473},
journal = {Nature Physics},
mendeley-groups = {Papers qubits},
number = {7},
pages = {21},
publisher = {Nature Publishing Group},
title = {{Dynamical decoupling and noise spectroscopy with a superconducting flux qubit}},
url = {http://arxiv.org/abs/1101.4707},
volume = {7},
year = {2011}
}


@article{Johansson2011,
archivePrefix = {arXiv},
arxivId = {1110.0573v2},
author = {Johansson, J. R. and Nation, P. D. and Nori, F.},
eprint = {1110.0573v2},
mendeley-groups = {Papers qubits},
title = {{QuTiP: An open-source Python framework for the dynamics of open quantum systems}},
year = {2011}
}



@article{Bader2013,
author = {Bader, S.},
file = {:home/gleb/Документы/Mendeley Desktop/The Transmon Qubit Theory - Bader - 2013.pdf:pdf},
mendeley-groups = {Papers qubits},
title = {{The Transmon Qubit Theory}},
year = {2013}
}

@article{bozyigit2011,
  title={Antibunching of microwave-frequency photons observed in correlation measurements using linear detectors},
  author={Bozyigit, D. and Lang, C. and Steffen, L. and Fink, J. M. and Eichler, C. and Baur, M. and Bianchetti, R. and Leek, P. J. and Filipp, S. and Da Silva, M. P. and others},
  journal={Nature Physics},
  volume={7},
  number={2},
  pages={154--158},
  year={2011},
  publisher={Nature Publishing Group}
}
@article{Majer2007,
  title={Coupling superconducting qubits via a cavity bus},
  author={Majer, J. and Chow, J. M. and Gambetta, J. M. and Koch, J. and Johnson, B. R. and Schreier, J. A. and Frunzio, L. and Schuster, D. I. and Houck, A. A. and Wallraff, A. and others},
  journal={Nature},
  volume={449},
  number={7161},
  pages={443--447},
  year={2007},
  publisher={Nature Publishing Group}
}


@article{Blais2004,
abstract = {We propose a realizable architecture using one-dimensional transmission line resonators to reach the strong coupling limit of cavity quantum electrodynamics in superconducting electrical circuits. The vacuum Rabi frequency for the coupling of cavity photons to quantized excitations of an adjacent electrical circuit (qubit) can easily exceed the damping rates of both the cavity and the qubit. This architecture is attractive both as a macroscopic analog of atomic physics experiments and for quantum computing and control, since it provides strong inhibition of spontaneous emission, potentially leading to greatly enhanced qubit lifetimes, allows high-fidelity quantum non-demolition measurements of the state of multiple qubits, and has a natural mechanism for entanglement of qubits separated by centimeter distances. In addition it would allow production of microwave photon states of fundamental importance for quantum communication.},
archivePrefix = {arXiv},
arxivId = {cond-mat/0402216},
author = {Blais, A. and Huang, R.-S. and Wallraff, A. and Girvin, S. M. and Schoelkopf, R. J.},
doi = {10.1103/PhysRevA.69.062320},
eprint = {0402216},
pages = {14},
title = {{Cavity quantum electrodynamics for superconducting electrical circuits: an architecture for quantum computation}},
url = {http://arxiv.org/abs/cond-mat/0402216},
year = {2004}
}


@article{Koch2007,
arxivId = {cond-mat/0703002},
author = {Koch, J. and Yu, T. M. and Gambetta, J. M. and Houck, A. A. and Schuster, D. I. and Majer, J. and Blais, A. and Devoret, M. H. and Girvin, S. M. and Schoelkopf, R. J.},
doi = {10.1103/PhysRevA.76.042319},
eprint = {0703002},
file = {:home/gleb/Документы/Mendeley Desktop/Charge insensitive qubit design derived from the Cooper pair box - Koch et al. - 2007.pdf:pdf},
mendeley-groups = {Papers qubits},
pages = {21},
primaryClass = {cond-mat},
title = {{Charge insensitive qubit design derived from the Cooper pair box}},
url = {http://arxiv.org/abs/cond-mat/0703002},
year = {2007}
}


@article{yan2015,
  title={The flux qubit revisited},
  author={Yan, F. and Gustavsson, S. and Kamal, A. and Birenbaum, J. and Sears, A. P.  and Hover, D. and Gudmundsen, T. J. and Yoder, J. L. and Orlando, T. P. and Clarke, J. and others},
  journal={Preprint at http://arxiv. org/abs/1508.06299},
  year={2015}
}


@book{pozar2012,
  title={Microwave Engineering, copyright 2012 by John Wiley \& Sons},
  author={Pozar, D. M.},
  publisher={Inc}
}

@article{Goppl2008,
abstract = {We have designed and fabricated superconducting coplanar waveguide resonators with fundamental frequencies from 2 to \$9 \backslash rm\{GHz\}\$ and loaded quality factors ranging from a few hundreds to a several hundred thousands reached at temperatures of \$20 \backslash rm\{mK\}\$. The loaded quality factors are controlled by appropriately designed input and output coupling capacitors. The measured transmission spectra are analyzed using both a lumped element model and a distributed element transmission matrix method. The experimentally determined resonance frequencies, quality factors and insertion losses are fully and consistently characterized by the two models for all measured devices. Such resonators find prominent applications in quantum optics and quantum information processing with superconducting electronic circuits and in single photon detectors and parametric amplifiers.},
archivePrefix = {arXiv},
arxivId = {0807.4094},
author = {G\"{o}ppl, M. and Fragner, A. and Baur, M. and Bianchetti, R. and Filipp, S. and Fink, J. M. and Leek, P. J. and Puebla, G. and Steffen, L. and Wallraff, A.},
doi = {10.1063/1.3010859},
eprint = {0807.4094},
file = {:C$\backslash$:/Users/gleb/Documents/Mendeley Desktop/0807.4094v1.pdf:pdf},
isbn = {00218979},
issn = {00218979},
journal = {Journal of Applied Physics},
mendeley-groups = {Papers qubits},
number = {11},
pages = {1--8},
title = {{Coplanar waveguide resonators for circuit quantum electrodynamics}},
volume = {104},
year = {2008}
}

@phdthesis{Kiselev2013,
author = {Kiselev, E.},
file = {:C$\backslash$:/Users/gleb/Documents/Mendeley Desktop/ba\_Kiselev(2).pdf:pdf},
title = {{Design and Measurement of Superconducting Spiral Microwave Resonators}},
year = {2013}
}

@article{Bishop2010,
abstract = {Circuit Quantum Electrodynamics (cQED), the study of the interaction between superconducting circuits behaving as artificial atoms and 1-dimensional transmission-line resonators, has shown much promise for quantum information processing tasks. For the purposes of quantum computing it is usual to approximate the artificial atoms as 2-level qubits, and much effort has been expended on attempts to isolate these qubits from the environment and to invent ever more sophisticated control and measurement schemes. Rather than focussing on these technological aspects of the field, this thesis investigates the opportunities for using these carefully engineered systems for answering questions of fundamental physics.},
archivePrefix = {arXiv},
arxivId = {1007.3520},
author = {Bishop, L. S.},
eprint = {1007.3520},
file = {:home/gleb/Документы/Mendeley Desktop/Circuit Quantum Electrodynamics - Bishop - 2010.pdf:pdf},
isbn = {9780549067177},
mendeley-groups = {Dissers},
pages = {168},
publisher = {Yale University},
title = {{Circuit Quantum Electrodynamics}},
url = {http://arxiv.org/abs/1007.3520},
year = {2010}
}