Diffraction, Fourier Optics and Imaging

Chapter 12 - Wave Propagation in Inhomogeneous Media

12.1   INTRODUCTION

In previous chapters, the index of refraction n(x, y, z) was assumed to be constant,
independent of position. In many applications, such as wave propagation in optical
fibers, volume diffraction gratings, photorefractive media, and so on, n(x, y, z) is
actually not constant. Then, analysis becomes much more difficult, and often
numerical methods are used to analyze wave propagation in such media. Some
methods used are pseudospectral, such as the beam propagation method (BPM)
discussed in Sections 12.4 and 12.5, whereas others are usually based on finite
difference or finite element methods.

The BPM method discussed in this chapter is based on the paraxial wave equation
for inhomogeneous media, is valid for propagation near the z-axis, and has several
other restrictions. Its main advantage is that it is computed fast with the FFT and is
sufficiently accurate in a large number of applications. For wide-angle propagation,
other BPM algorithms exist, and they are usually based on the finite difference
method. This is further discussed in Chapter 19 in the context of dense wavelength
division multiplexing/demultiplexing for optical communications and networking.

This chapter consists of five sections. Section 12.2 discusses the Helmholtz
equation for inhomogeneous media. The paraxial wave equation for homogeneous
media discussed in Section 5.4 is generalized to inhomogeneous media in Section
12.3. The BPM as a prominent numerical method employing the FFT for wave
propagation in inhomogeneous media is introduced in Section 12.4. A particular
example of how the BPM is used in practice is the directional coupler illustrated in
Section 12.5. This is an optical device consisting of two dielectric wave guides
placed nearby so that an optical wave launched into one guide can be coupled into
the other. Such devices are of common use in optical communications and
networking. It is shown that the BPM gives results sufficiently accurate as compared
with the rigorous coupled mode theory. As the coupled mode theory cannot be
utilized in more complex designs, the BPM is usually the method of choice in the
analysis and synthesis of such devices involving wave propagation in inhomogeneous
media.

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