Coherent Optics: Fundamentals and Applications
Since the advent of the laser, coherent optics has developed at an ever increasing pace. There is no doubt about the reason. Coherent light, with its properties so different from the light we are surrounded by, lends itself to numerous applications in science, technology, and life. The bandwidth of coherent optics reaches from holography and interferometry, with its gravitational wave detectors, to the CD player for music, movies, and computers; from the laser scalpel, which allows surgical cutting in the interior of the eye without destruction of the layers penetrated in front of it, to optical information and data processing with its great impact on society. According to its importance, the foundations of coherent optics should be conveyed to students of natural sciences as early as possible to better prepare them for their future careers as physicists or engineers. The present book tries to serve this need: to promote the foundations of coherent optics. Special attention is paid to a thorough presentation of the fundamentals. This should enable the reader to follow the contemporary literature from a firm basis. The wealth of material, of course, makes necessary a restriction of the topics included. Therefore, from the main areas of optics, wave optics and the classical description oflight is given most ofthe space available. The book starts with a quick trip through the history of physics from the viewpoint of optics.
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The Main Areas of Optics
Fundamentals of Wave Optics
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absorption amplitude angle aperture approximation arrangement autocorrelation beam splitter bifurcation calculated cavity coherence function coherent light complex conjugate image constant contrast function convolution corresponding dependence diameter diffraction pattern digital hologram dispersion distance electric field electron energy Fabry-Perot interferometer fiber field amplitude filter Fourier transform Gaussian given grating group velocity harmonic wave hologram holographic plate illuminated interference fringes interference pattern laser level laser light length lens light field light source light wave linear maximum measuring medium method Michelson interferometer mirror mode locking modulation monofrequency nonlinear object wave obtained optical axis oscillation output parameter partial waves phase conjugate photographic photon plane wave point source polarization power spectrum propagation pump Q-switching quantum reconstruction recording reference wave reflected refractive index resonator screen signal solitons solution spatial frequency speckle pattern spectral spherical wave spontaneous emission superposition term three-wave interaction tion ultrashort pulse wave equation wave field wavelength width yields