Wiley Series in Pure and Applied Optics

Liquid crystals are a state of matter that possess properties of both solid and liquids. Owing to its unique physical properties, liquid crystals have found important applications in optics and optoelectronics, including the expanding technology of flat panels. This book presents an engineering-oriented, practical treatment of the optics of liquid crystal displays. It covers all aspects of the technology, beginning with the simplest case of plane wave propagation in homogeneous media, and gradually building up to more advanced concepts. With few books available even on related subjects, this title certainly fills a gap in the field.

Describes how laser radiation propagates in natural and artificial materials and how the state of radiation can be controlled and manipulated (phase intensity, polarization) by various means. New concepts and useful techniques are described in the problems. Includes many figures, tables, and examples.

Optical Waves in Layered Media presents a clear picture of the propagation of optical waves in layered media and teaches the reader how to design and analyze optical devices using such media. Starting from the simplest case of plane wave propagation in homogeneous media, the author introduces a new matrix method for studying the optical properties of multilayer structures consisting of isotropic materials. He then describes propagation in anisotropic layered media and in inhomogeneous layers, guided waves, the coupling of modes, and the optical properties of superlattices and quantum wells.

Optical Waves in Layered Media bridges the gap between theory and practice by means of numerical examples based on real-life situations.

Bridging the gap between theory and practice, it clarifies important phenomena in photorefractive media and shows how to apply these phenomena in actual situations. While the focus is on the theory of propagation of optical waves and the mixing of electromagnetic radiation in these media, there are also many numerical examples based on real-world situations included for hands-on guidance. In addition to exploring the basics of electromagnetic waves and periodic structures, this practical guide discusses optical phase conjugators and photorefractive resonators; covers fundamental properties of gratings and holograms; details how to use optical information processing, optical interconnection and neural networks; and treats high-order photorefractive effects in optical fibers.