The lecture is focused on the guided wave theory and its application to the design of guided wave circuit in microwave, millimeter-wave and optical frequency regions. Topics included are electromagnetic fields in waveguides, the dispersion and nonlinearity of optical fibers, a coupled mode theory, electromagnetic waves in a periodic structure, scattering matrix representation, eigen excitation, and the design of guided wave circuits.
The lecture is focused on the guided wave theory and its application to the design of guided wave circuit in microwave, millimeter-wave and optical frequency regions. Topics included are electromagnetic fields in waveguides, the dispersion and nonlinearity of optical fibers, a coupled mode theory, electromagnetic waves in a periodic structure, scattering matrix representation, eigen excitation, and the design of guided wave circuits.
01. Introduction to waveguide
02. Transmission lines
03. Plane wave propagation
04. Planar waveguides for microwave and millimeter-wave
05. Metalic hollow waveguides
06. Optical planar waveguides
07. Wave propagation in optical fibers (dispersion and nonlinearity)
08. Coupled mode equation
09. Guided waves in periodic structures
10. Circuit representation by a scattering matrix
11. Eigen excitation and eigen values
12. Couplers and dividers
13. Resonators, filters and multi/demultiplexers
14. Nonreciprocal circuits
Reference: D.Marcuse, "Theory of Dielectric Waveguides," Academic Press.
R.E.Collin, "Field theory of guided waves," McGraw-Hill.
J.Helszajn, "Passive and active microwave circuits," John Wiley & Sons.
Fundamentals on the electromagnetic wave transmission for undergraduate course students are required.
Evaluation is based on the term end examination.
Tetsuya Mizumoto E-mail: tmizumotツシpe.titech.ac.jp
Anytime you can visit my office with permission by email at tmizumot@pe.titech.ac.jp