光学中的数学模型
2011-2
清华大学出版社
(美)包刚 等著
333
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this volume addresses recent developments in
mathematical modeling in three areas of optical science:
diffractive optics, photonic band gap structures, and waveguides.
particular emphasis is on the formulation of mathematical models
and the design and analysis of new computational approaches. the
book contains cutting-edge discourses on areas motivated by
emerging technology in optics that provide significant challenges
and opportunities for applied mathematicians, researchers, and
engineers.
each of the three topics is presented through a series of survey
papers to provide a broad overview focusing on the mathematical
models. chapters are organized to present model problems, physical
principles, mathematical and computational approaches, and
engineering applications corresponding to each of the three areas.
while some of the subject matter is classical, the topics presented
are new and represent the latest developments in their respective
fields.
this book is intended to help researchers and especially graduate
students gain broad exposure to model problems in the areas of
optical science:diffractive optics, photonic band gap structures,
and waveguides. it includes up-to-date results and references for
more experienced researchers while providing introductory material
for those less familiar with these areas.
foreword
preface
chapter 1
overview and applications of diffractive optics technology
j. allen cox
chapter 2
variational methods for diffractive optics modeling
gang bao and david c. dobson
chapter 3
high-order boundary perturbation methods
oscar p. bruno and fernando reitich
chapter 4
mathematical reflections on the fourier modal method in grating
theory
lifeng li
chapter 5
electromagnetic models for finite aperiodic diffractive optical
elements
dennis w. prather, mark s. mirotznik, and shouyuan shi
chapter 6
analysis of the diffraction from chiral gratings
Periodic structures (gratings) have received increasing attention through the years because of important applications in integrated optics, optical lenses, antire-flective structures, holography, lasers, communication, and computing. Significant mathematical results on periodic achiral structures may be found in Bao and Dob-son, tBao, Dobson, and Cox , Chen and Friedman , Ned61ec and Starling , Dofoson and Friedman, Dobson , Abboud , Bruno and R,eitich ,and Bao. Chiral gratings provide an exciting combination of the medium and structure.The combination gives rise to new features and applications. For instance, chiral gratings are capable of converting a linearly polarized incident field into two nearly circularly polarized diffracted modes in different directions. For various physical and computational aspects of the electromagnetic wave propagation inside periodic chiral media, we refer to Jaggar et al. , Lakhtakia,Varadan, and Varadan , and Yueh and Kong . Jaggar et al. have inves- tigated the electromagnetic properties of a structure with sinusoidally periodic per- mittivity, permeability, and chirality admittance by using coupled-mode equations linking forward and backward propagating waves of opposite circular polarizations. Lakhtakia, Varadan, and Varadan have investigated a similar problem with a different approach. They have obtained coupled first-order differential equations for reduced fields and analyzed a piecewise constant case and a constant impedance case. Lakhtakia, Varadan, and Varadan have solved wave scattering at an in-terface with a singly periodic geometry separating a chiral medium from an achiral one by a fully vectorial treatment and have studied the reflection and transmission characteristics of these gratings. Yueh and Kong have analyzed the diffraction of waves by chiral gratings placed over a dielectric substrate, for arbitrary angles of incidence and polarizations, by a generalization of the coupled wave theory. Numer-ical examples have been given to illustrate the effects of chirality on the polarization states of waves diffracted by gratings with rectangular grooves. It has been found that the chiral grating is able to more evenly distribute the power between Floquet modes and also to make modes nearly circularly. In this chapter, we consider a time-harmonic electromagnetic plane wave in-cident on a very general biperiodic structure in R3. By biperiodic structure or doubly periodic structure, we mean that the structure is periodic in two orthog- onal directions. The periodic structure separates two chiral homogeneous regions. The medium inside the structure is chiral and non,homogen,eous. The study of the propagation of the refiected and transmitted waves away from the structure is the diffraction problem. The purpose of this chapter is to introduce a variational formulation of the dif-fraction problem by chiral gratings. The main result is concerned with the well-pos-edness of the model problem. It is shown that for all but possibly a discrete set of fre-quencies, there is a uruque quasi-periodic weak solution to the diffraction problem.The approach is based on a Hodge decomposition, and a compact imbeddin,g result. ……
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没细看,和我想象的数学模型有点差距
还么看
这本书记录数学模型在三个光学领域的进展:衍射光学,光子带隙结构和波导,特别注重于数学模型和设计的公式化,分析新的计算方法.边缘学科的产生于新技术密切相关,这些技术是应用数学家,研究者,工程师的巨大挑战和机遇。
每个领域都聚焦于数学模型,基于一系列的调查报告,视野宽阔。在篇章组织方面依据:提出模型问题,物理原理,数学方法,计算方法,与之相关的数学应用。于此同时,某些问题是经典的,但谈及的方法是新的,并列举了最新的进展。
这本书得目的在于:为毕业生在衍射光学,光子带隙结构和波导三个方向,对光学模型的模拟提供足够的训练,为研究者提供最新进展和参考文献。同时,对不够熟悉这个领域的人提供介绍性的材料。