6.453 Quantum Optical Communication, Fall 2004
This course is offered to graduate students and covers topics in five major areas of quantum optical communication: quantum optics, single-mode and two-mode quantum systems, multi-mode quantum systems, nonlinear optics, and quantum systems theory. From the course home page: Course Description This c...
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| Language: | en-US |
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2004
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| Online Access: | http://hdl.handle.net/1721.1/55907 |
| _version_ | 1811081257212182528 |
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| author | Shapiro, Jeffrey H. (Jeffrey Howard) |
| author_facet | Shapiro, Jeffrey H. (Jeffrey Howard) |
| author_sort | Shapiro, Jeffrey H. (Jeffrey Howard) |
| collection | MIT |
| description | This course is offered to graduate students and covers topics in five major areas of quantum optical communication: quantum optics, single-mode and two-mode quantum systems, multi-mode quantum systems, nonlinear optics, and quantum systems theory. From the course home page: Course Description This course is offered to graduate students and covers topics in five major areas of quantum optical communication: quantum optics, single-mode and two-mode quantum systems, multi-mode quantum systems, nonlinear optics, and quantum systems theory. Specific topics include the following. Quantum optics: Dirac notation quantum mechanics; harmonic oscillator quantization; number states, coherent states, and squeezed states; radiation field quantization and quantum field propagation; P-representation and classical fields. Linear loss and linear amplification: commutator preservation and the Uncertainty Principle; beam splitters; phase-insensitive and phase-sensitive amplifiers. Quantum photodetection: direct detection, heterodyne detection, and homodyne detection. Second-order nonlinear optics: phase-matched interactions; optical parametric amplifiers; generation of squeezed states, photon-twin beams, non-classical fourth-order interference, and polarization entanglement. Quantum systems theory: optimum binary detection, quantum precision measurements, quantum cryptography, and quantum teleportation. |
| first_indexed | 2024-09-23T11:43:53Z |
| id | mit-1721.1/55907 |
| institution | Massachusetts Institute of Technology |
| language | en-US |
| last_indexed | 2024-09-23T11:43:53Z |
| publishDate | 2004 |
| record_format | dspace |
| spelling | mit-1721.1/559072019-09-12T18:59:51Z 6.453 Quantum Optical Communication, Fall 2004 Quantum Optical Communication Shapiro, Jeffrey H. (Jeffrey Howard) Quantum optics: Dirac notation quantum mechanics harmonic oscillator quantization number states, coherent states, and squeezed states radiation field quantization and quantum field propagation P-representation and classical fields Linear loss and linear amplification: commutator preservation and the Uncertainty Principle beam splitters phase-insensitive and phase-sensitive amplifiers Quantum photodetection: direct detection, heterodyne detection, and homodyne detection Second-order nonlinear optics: phasematched interactions optical parametric amplifiers generation of squeezed states, photon-twin beams, non-classical fourth-order interference, and polarization entanglement Quantum systems theory: optimum binary detection quantum precision measurements quantum cryptography quantum teleportation This course is offered to graduate students and covers topics in five major areas of quantum optical communication: quantum optics, single-mode and two-mode quantum systems, multi-mode quantum systems, nonlinear optics, and quantum systems theory. From the course home page: Course Description This course is offered to graduate students and covers topics in five major areas of quantum optical communication: quantum optics, single-mode and two-mode quantum systems, multi-mode quantum systems, nonlinear optics, and quantum systems theory. Specific topics include the following. Quantum optics: Dirac notation quantum mechanics; harmonic oscillator quantization; number states, coherent states, and squeezed states; radiation field quantization and quantum field propagation; P-representation and classical fields. Linear loss and linear amplification: commutator preservation and the Uncertainty Principle; beam splitters; phase-insensitive and phase-sensitive amplifiers. Quantum photodetection: direct detection, heterodyne detection, and homodyne detection. Second-order nonlinear optics: phase-matched interactions; optical parametric amplifiers; generation of squeezed states, photon-twin beams, non-classical fourth-order interference, and polarization entanglement. Quantum systems theory: optimum binary detection, quantum precision measurements, quantum cryptography, and quantum teleportation. 2004-12 6.453-Fall2004 local: 6.453 local: IMSCP-MD5-58a5457edf6c2c056cfd53829d50441d http://hdl.handle.net/1721.1/55907 en-US Usage Restrictions: This site (c) Massachusetts Institute of Technology 2003. Content within individual courses is (c) by the individual authors unless otherwise noted. The Massachusetts Institute of Technology is providing this Work (as defined below) under the terms of this Creative Commons public license ("CCPL" or "license"). The Work is protected by copyright and/or other applicable law. Any use of the work other than as authorized under this license is prohibited. By exercising any of the rights to the Work provided here, You (as defined below) accept and agree to be bound by the terms of this license. The Licensor, the Massachusetts Institute of Technology, grants You the rights contained here in consideration of Your acceptance of such terms and conditions. text/html Fall 2004 |
| spellingShingle | Quantum optics: Dirac notation quantum mechanics harmonic oscillator quantization number states, coherent states, and squeezed states radiation field quantization and quantum field propagation P-representation and classical fields Linear loss and linear amplification: commutator preservation and the Uncertainty Principle beam splitters phase-insensitive and phase-sensitive amplifiers Quantum photodetection: direct detection, heterodyne detection, and homodyne detection Second-order nonlinear optics: phasematched interactions optical parametric amplifiers generation of squeezed states, photon-twin beams, non-classical fourth-order interference, and polarization entanglement Quantum systems theory: optimum binary detection quantum precision measurements quantum cryptography quantum teleportation Shapiro, Jeffrey H. (Jeffrey Howard) 6.453 Quantum Optical Communication, Fall 2004 |
| title | 6.453 Quantum Optical Communication, Fall 2004 |
| title_full | 6.453 Quantum Optical Communication, Fall 2004 |
| title_fullStr | 6.453 Quantum Optical Communication, Fall 2004 |
| title_full_unstemmed | 6.453 Quantum Optical Communication, Fall 2004 |
| title_short | 6.453 Quantum Optical Communication, Fall 2004 |
| title_sort | 6 453 quantum optical communication fall 2004 |
| topic | Quantum optics: Dirac notation quantum mechanics harmonic oscillator quantization number states, coherent states, and squeezed states radiation field quantization and quantum field propagation P-representation and classical fields Linear loss and linear amplification: commutator preservation and the Uncertainty Principle beam splitters phase-insensitive and phase-sensitive amplifiers Quantum photodetection: direct detection, heterodyne detection, and homodyne detection Second-order nonlinear optics: phasematched interactions optical parametric amplifiers generation of squeezed states, photon-twin beams, non-classical fourth-order interference, and polarization entanglement Quantum systems theory: optimum binary detection quantum precision measurements quantum cryptography quantum teleportation |
| url | http://hdl.handle.net/1721.1/55907 |
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