Fundamentals Of Photonics Saleh Solution Manual !!BETTER!!
Fundamentals Of Photonics Saleh Solution Manual
Introduction To Photonics: The course provides the students with a background of the photonic band structures, the science of light and its interaction with different materials. Experimental demonstrations are given on the physics of light. The class will be discussed in terms of its theoretical and practical nature, i.e. its ability to excite interest and curiosity in physics, mathematics, computing and electronics.
This course is mainly centered on optical materials and their interaction with light. It also presents the fundamentals of computer vision and image processing. The course covers optical materials and their properties as well as computational methods for the representation, numerical simulation, and analysis of materials such as optics, electronics, and electromagnetics.
The first part of this study is to analyze the general solution of the optical vortex propagation in the multimode fiber. For a demonstration of the method, in section 2, the solution of propagation of the optical vortex of different orders is given in terms of the Heun’s functions [6-9]. In section 3, the Heun’s function representation of the optical vortex is presented with some new results such as analysis of the effect of the distance between the cores for the propagation of optical vortex and the specific refractive index. The relationship between the propagation distance and the radius of the first core is analyzed in detail. The propagation distance is also presented with respect to the core size and the difference between the refractive indices. To study the variation of the optical vortex field with distance, the order of the optical vortex is fixed and the core size is varied. In section 4, the analytical expressions of the light intensities of the light vortex and the astigmatic beam propagating through a multicore fiber are presented. Different parameters such as the number of cores, core size, their distances from each other and their refractive indices are considered in the analysis. The light intensities are also provided with respect to the core size and the distance between them.
Introduction to photonics. Combination of right and left handed materials. Definition of the index of refraction. Readings: (residual angular momentum and its related spin effects). The attention is focused on spin-orbit coupling effects. Existence of spin polarized states in silicon and germanium. Scattering of light from dielectrics and from metals. Dispersion relation for light travelling in the electric field. Spin-orbit interaction and the selection rule.
Introduction to optics and classical and quantum theories with a particular focus on the properties of light. The theory of phase retardation, the basic laws of reflection and refraction, the refractive index, the optical theorem, the Snell’s law and refraction at a boundary. Introduction to the concepts of diffraction and interference. Spatial and temporal focusing. Diffraction through narrow slits.Spherical waves, Bessel functions, the paraxial approximation. The geometrical optics limit. The classical ray theory.The wave theory of light. The role of the wavefunction. The light cone and the optical path. The Schrödinger equation and the transport of photon. The Heisenberg uncertainty principle and the phase of light. The conservation of the phase of the quantum mechanical wave function, the photon. Light wave packets. Detection of light. Conservation of the photon momentum. Evolution of the photon wave packets. Coherent and incoherent radiation and their detection. Spontaneous and induced emission. Stimulated emission and atomic fluorescence. Stokes components. The concept of threshold fluorescence. Description of atomic and molecular absorption. Explanation of fluorescenceemission and depletion processesSelecting of specific excitation lines and development of spectrographs. Typical application of the concepts of the above paragraphs: spectrographs for single line spectroscopy, spectrographs for maser-based experiments, the analysis of fluorescence emissions from molecules as well as studies of high-resolution absorption spectra, line velocities, and profiles of emission spectra. Determination of line parameters, results of experimental and numerical measurements of laser parameters, spectra and wave fronts of lasers. Selection of grating materials for spectrographs.