Numerical Simulation of Optical Wave Propagation With Examples in MATLAB Jason D. Schmidt o59$vX,
Vq{3:QBR
Description 0jjtx'F
bJD$!*r\%!
Wave-optics simulation is an immensely useful tool for many applications. The simulation techniques in this book are directly applicable to atmospheric imaging, astronomy, adaptive optics, free-space optical communications, and LADAR. In addition, many of the basic techniques are applicable to integrated optics and nonlinear, anisotropic, and optically active media. |Nj6RB7
Za3}:7`Gu
Numerical Simulation of Optical Wave Propagation is solely dedicated to wave-optics simulations. The book discusses digital Fourier transforms (FT), FT-based operations, multiple methods of wave-optics simulations, sampling requirements, and simulations in atmospheric turbulence. +`{OOp=
a@qc?
This book will benefit optical scientists and engineers at all levels as a guide for FT-based data analysis, imaging system analysis, and wave-optics simulations. Professors can use this book to augment their Fourier optics courses and for independent studies with students. Problem sets are given at the end of each chapter. Students will learn principles and techniques from this book that can be utilized throughout their careers in optics. w=rD8@
EEL3~H{(
Table of Contents hKWWN`;b !
c>^(=52Q
1. Foundations of Scalar Diffraction Theory Yb/*2iWX
2. Digital Fourier Transforms nQ_{IO8/6W
3. Simple Computations Using Fourier Transforms P#XV_2
4. Fraunhofer Diffraction and Lenses {$yju _[
5. Imaging Systems and Aberrations <.gDg?'3
6. Fresnel Diffraction in Vacuum F N=WU<
5
7. Sampling Requirements for Fresnel Diffraction GbL1<P$V
8. Relaxed Sampling Constraints with Partial Propagations )=29Hm"
9. Propagation through Atmospheric Turbulence SZHgXl3:
Appendix A: Function Definitions b"N!#&O