RSS Feed for optical communication https://solvonauts.org/%3Faction%3Drss_search%26term%3Doptical+communication RSS Feed for optical communication 6.161 Modern Optics Project Laboratory (MIT) 6.161 Modern Optics Project Laboratory (MIT) 6 161 explores modern optics through lectures laboratory exercises and projects Topics covered include polarization properties of light reflection and refraction coherence and interference Fraunhofer and Fresnel diffraction imaging and transforming properties of lenses spatial filtering coherent optical processors holography optical properties of materials lasers nonlinear optics electro optic and acousto optic materials and devices optical detectors fiber optics and optical communication This course is worth 12 Engineering Design Points 6 161 explores modern optics through lectures laboratory exercises and projects Topics covered include polarization properties of light reflection and refraction coherence and interference Fraunhofer and Fresnel diffraction imaging and transforming properties of lenses spatial filtering coherent optical processors holography optical properties of materials lasers nonlinear optics electro optic and acousto optic materials and devices optical detectors fiber optics and optical communication This course is worth 12 Engineering Design Points http://dspace.mit.edu/handle/1721.1/35265 http://dspace.mit.edu/handle/1721.1/35265 6.013 Electromagnetics and Applications (MIT) 6.013 Electromagnetics and Applications (MIT) Includes audio video content AV special element video This course explores electromagnetic phenomena in modern applications including wireless and optical communications circuits computer interconnects and peripherals microwave communications and radar antennas sensors micro electromechanical systems and power generation and transmission Fundamentals include quasistatic and dynamic solutions to Maxwell s equations waves radiation and diffraction coupling to media and structures guided waves resonance acoustic analogs and forces power and energy Includes audio video content AV special element video This course explores electromagnetic phenomena in modern applications including wireless and optical communications circuits computer interconnects and peripherals microwave communications and radar antennas sensors micro electromechanical systems and power generation and transmission Fundamentals include quasistatic and dynamic solutions to Maxwell s equations waves radiation and diffraction coupling to media and structures guided waves resonance acoustic analogs and forces power and energy http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-013-electromagnetics-and-applications-spring-2009 http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-013-electromagnetics-and-applications-spring-2009 6.453 Quantum Optical Communication (MIT) 6.453 Quantum Optical Communication (MIT) 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 nbsp Quantum optics nbsp 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 nbsp 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 a 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 nbsp Quantum optics nbsp 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 nbsp 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 a http://dspace.mit.edu/handle/1721.1/55907 http://dspace.mit.edu/handle/1721.1/55907 6.453 Quantum Optical Communication (MIT) 6.453 Quantum Optical Communication (MIT) 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 Dirac notation quantum mechanics harmonic oscillator quantization number states coherent states and squeezed states P representation and classical fields direct homodyne and heterodyne detection linear propagation loss phase insensitive and phase sensitive amplifiers entanglement and teleportation field quantization quantum photodetection phase matched interactions optical parametric amplifiers generation of squeezed states photon twin beams non classical fourth order interference and pola 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 Dirac notation quantum mechanics harmonic oscillator quantization number states coherent states and squeezed states P representation and classical fields direct homodyne and heterodyne detection linear propagation loss phase insensitive and phase sensitive amplifiers entanglement and teleportation field quantization quantum photodetection phase matched interactions optical parametric amplifiers generation of squeezed states photon twin beams non classical fourth order interference and pola http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-453-quantum-optical-communication-fall-2008 http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-453-quantum-optical-communication-fall-2008 6.161 Modern Optics Project Laboratory (MIT) 6.161 Modern Optics Project Laboratory (MIT) 6 161 offers an introduction to laboratory optics optical principles and optical devices and systems This course covers a wide range of topics including polarization properties of light reflection and refraction coherence and interference Fraunhofer and Fresnel diffraction holography imaging and transforming properties of lenses spatial filtering two lens coherent optical processor optical properties of materials lasers electro optic acousto optic and liquid crystal light modulators optical detectors optical waveguides and fiber optic communication systems Students engage in extensive oral and written communication exercises There are 12 engineering design points associated with this subject 6 161 offers an introduction to laboratory optics optical principles and optical devices and systems This course covers a wide range of topics including polarization properties of light reflection and refraction coherence and interference Fraunhofer and Fresnel diffraction holography imaging and transforming properties of lenses spatial filtering two lens coherent optical processor optical properties of materials lasers electro optic acousto optic and liquid crystal light modulators optical detectors optical waveguides and fiber optic communication systems Students engage in extensive oral and written communication exercises There are 12 engineering design points associated with this subject http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-161-modern-optics-project-laboratory-fall-2005 http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-161-modern-optics-project-laboratory-fall-2005 6.977 Ultrafast Optics (MIT) 6.977 Ultrafast Optics (MIT) This course is offered to graduate students and addresses issues regarding ultrafast optics Topics covered include Generation propagation and applications of ultrashort pulses nano pico femto attosecond pulses Linear and nonlinear pulse shaping processes Optical solitons Pulse compression Laser principles Single and multi mode laser dynamics Q switching Active and passive mode locking Pulse characterization Autocorrelation FROG SPIDER Noise in mode locked lasers and its limitations in measurements Laser amplifiers optical parametric amplifiers and oscillators Applications in research and industry Pump probe techniques Optical imaging Frequency metrology Laser ablation High harmonic generation This course is offered to graduate students and addresses issues regarding ultrafast optics Topics covered include Generation propagation and applications of ultrashort pulses nano pico femto attosecond pulses Linear and nonlinear pulse shaping processes Optical solitons Pulse compression Laser principles Single and multi mode laser dynamics Q switching Active and passive mode locking Pulse characterization Autocorrelation FROG SPIDER Noise in mode locked lasers and its limitations in measurements Laser amplifiers optical parametric amplifiers and oscillators Applications in research and industry Pump probe techniques Optical imaging Frequency metrology Laser ablation High harmonic generation http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-977-ultrafast-optics-spring-2005 http://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-977-ultrafast-optics-spring-2005 6.013 Electromagnetics and Applications (MIT) This course explores electromagnetic phenomena in modern applications including wireless and optical communications circuits computer interconnects and peripherals microwave communications and radar antennas sensors micro electromechanical systems and power generation and transmission Fundamentals include quasistatic and dynamic solutions to Maxwell s equations waves radiation and diffraction coupling to media and structures guided waves resonance acoustic analogs and forces power and energy http://mit-ocw.sbu.ac.ir/Default.aspx?tabid=4069 http://mit-ocw.sbu.ac.ir/Default.aspx?tabid=4069 Optical Communication Systems Optical Communication Systems This course is a brief introduction to optical communication systems These systems are described focusing on lasers photodetectors fibers and design budgets The aim is qualifying students to design simple optical systems This course is a brief introduction to optical communication systems These systems are described focusing on lasers photodetectors fibers and design budgets The aim is qualifying students to design simple optical systems http://ocw.upm.es/teoria-de-la-senal-y-comunicaciones-1/optical-communication-systems http://ocw.upm.es/teoria-de-la-senal-y-comunicaciones-1/optical-communication-systems 6.161 Modern Optics Project Laboratory (MIT) 6 161 explores modern optics through lectures laboratory exercises and projects Topics covered include polarization properties of light reflection and refraction coherence and interference Fraunhofer and Fresnel diffraction imaging and transforming properties of lenses spatial filtering coherent optical processors holography optical properties of materials lasers nonlinear optics electro optic and acousto optic materials and devices optical detectors fiber optics and optical communication This course is worth 12 Engineering Design Points https://dspace.mit.edu/handle/1721.1/35265 https://dspace.mit.edu/handle/1721.1/35265 6.453 Quantum Optical Communication (MIT) 6.453 Quantum Optical Communication (MIT) 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 Dirac notation quantum mechanics harmonic oscillator quantization number states coherent states and squeezed states P representation and classical fields direct homodyne and heterodyne detection linear propagation loss phase insensitive and phase sensitive amplifiers entanglement and teleportation field quantization quantum photodetection phase matched interactions optical parametric amplifiers generation of squeezed states photon twin beams non classical fourth order interference and pola 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 Dirac notation quantum mechanics harmonic oscillator quantization number states coherent states and squeezed states P representation and classical fields direct homodyne and heterodyne detection linear propagation loss phase insensitive and phase sensitive amplifiers entanglement and teleportation field quantization quantum photodetection phase matched interactions optical parametric amplifiers generation of squeezed states photon twin beams non classical fourth order interference and pola https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-453-quantum-optical-communication-fall-2008 https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-453-quantum-optical-communication-fall-2008 6.013 Electromagnetics and Applications (MIT) This course explores electromagnetic phenomena in modern applications including wireless and optical communications circuits computer interconnects and peripherals microwave communications and radar antennas sensors micro electromechanical systems and power generation and transmission Fundamentals include quasistatic and dynamic solutions to Maxwell s equations waves radiation and diffraction coupling to media and structures guided waves resonance acoustic analogs and forces power and energy https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-013-electromagnetics-and-applications-spring-2009 https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-013-electromagnetics-and-applications-spring-2009 6.453 Quantum Optical Communication (MIT) 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 nbsp Quantum optics nbsp 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 nbsp 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 a https://dspace.mit.edu/handle/1721.1/55907 https://dspace.mit.edu/handle/1721.1/55907 6.161 Modern Optics Project Laboratory (MIT) 6 161 offers an introduction to laboratory optics optical principles and optical devices and systems This course covers a wide range of topics including polarization properties of light reflection and refraction coherence and interference Fraunhofer and Fresnel diffraction holography imaging and transforming properties of lenses spatial filtering two lens coherent optical processor optical properties of materials lasers electro optic acousto optic and liquid crystal light modulators optical detectors optical waveguides and fiber optic communication systems Students engage in extensive oral and written communication exercises There are 12 engineering design points associated with this subject https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-161-modern-optics-project-laboratory-fall-2005 https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-161-modern-optics-project-laboratory-fall-2005 6.977 Ultrafast Optics (MIT) This course is offered to graduate students and addresses issues regarding ultrafast optics Topics covered include Generation propagation and applications of ultrashort pulses nano pico femto attosecond pulses Linear and nonlinear pulse shaping processes Optical solitons Pulse compression Laser principles Single and multi mode laser dynamics Q switching Active and passive mode locking Pulse characterization Autocorrelation FROG SPIDER Noise in mode locked lasers and its limitations in measurements Laser amplifiers optical parametric amplifiers and oscillators Applications in research and industry Pump probe techniques Optical imaging Frequency metrology Laser ablation High harmonic generation https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-977-ultrafast-optics-spring-2005 https://ocw.mit.edu/courses/electrical-engineering-and-computer-science/6-977-ultrafast-optics-spring-2005 6.453 Quantum Optical Communication (MIT) 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 Dirac notation quantum mechanics harmonic oscillator quantization number states coherent states and squeezed states P representation and classical fields direct homodyne and heterodyne detection linear propagation loss phase insensitive and phase sensitive amplifiers entanglement and teleportation field quantization quantum photodetection phase matched interactions optical parametric amplifiers generation of squeezed states photon twin beams non classical fourth order interference and pola https://dspace.mit.edu/handle/1721.1/107407 https://dspace.mit.edu/handle/1721.1/107407