Fundamentals of PhotonicsFundamentals of Photonics: A complete, thoroughly updated, full-color second edition Now in a new full-color edition, Fundamentals of Photonics, Second Edition is a self-contained and up-to-date introductory-level textbook that thoroughly surveys this rapidly expanding area of engineering and applied physics. Featuring a logical blend of theory and applications, coverage includes detailed accounts of the primary theories of light, including ray optics, wave optics, electromagnetic optics, and photon optics, as well as the interaction of photons and atoms, and semiconductor optics. Presented at increasing levels of complexity, preliminary sections build toward more advanced topics, such as Fourier optics and holography, guided-wave and fiber optics, semiconductor sources and detectors, electro-optic and acousto-optic devices, nonlinear optical devices, optical interconnects and switches, and optical fiber communications. Each of the twenty-two chapters of the first edition has been thoroughly updated. The Second Edition also features entirely new chapters on photonic-crystal optics (including multilayer and periodic media, waveguides, holey fibers, and resonators) and ultrafast optics (including femtosecond optical pulses, ultrafast nonlinear optics, and optical solitons). The chapters on optical interconnects and switches and optical fiber communications have been completely rewritten to accommodate current technology. Each chapter contains summaries, highlighted equations, exercises, problems, and selected reading lists. Examples of real systems are included to emphasize the concepts governing applications of current interest. |
From inside the book
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Page 121
... aperture shadow , depending on the distance between the aperture and observation plane , the wavelength , and the dimensions of the aperture . An example is illustrated in Fig . 4.3-1 . It is difficult to determine exactly the manner in ...
... aperture shadow , depending on the distance between the aperture and observation plane , the wavelength , and the dimensions of the aperture . An example is illustrated in Fig . 4.3-1 . It is difficult to determine exactly the manner in ...
Page 122
... aperture on the back of the screen are question- able since the transmitted wave propagates in all directions and therefore reaches those points as well . A theory of diffraction based on the exact solution of the Helmholtz equation ...
... aperture on the back of the screen are question- able since the transmitted wave propagates in all directions and therefore reaches those points as well . A theory of diffraction based on the exact solution of the Helmholtz equation ...
Page 137
... aperture plane . The object is placed at a sub - wavelength distance from the aperture ( usually less than half the diameter of the aperture ) so that the beam illuminates a sub - wavelength - size area of the object . Upon transmission ...
... aperture plane . The object is placed at a sub - wavelength distance from the aperture ( usually less than half the diameter of the aperture ) so that the beam illuminates a sub - wavelength - size area of the object . Upon transmission ...
Common terms and phrases
absorption amplifier angle angular aperture approximation atoms axis band bandgap bandwidth Bragg carriers Chapter chirp coherence complex amplitude components corresponding detector determined device dielectric diffraction direction dispersion distance distribution electric field electro-optic electromagnetic electron emitted energy levels example factor Figure filter Fourier transform frequency function GaAs gain coefficient Gaussian beam group velocity Helmholtz equation holes illustrated in Fig incident input intensity interaction laser diodes layer lens light linear material matrix medium mirror modulator monochromatic n₁ Nonlinear Optics number of modes optical fiber optical power optical wave oscillation output parameter paraxial photon flux photon-flux density Photonic Crystals plane wave polarization pulse pump quantum R₁ radiation random ray optics recombination reflection refractive index region relation resonator result semiconductor shown in Fig spatial spectral width spontaneous emission thermal transition valence band vector w₁ wave traveling wavefronts wavefunction waveguide wavelength wavevector