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 regime. Topics included are electromagnetic waves in waveguides, dispersion in an optical fiber, coupled mode theory, electromagnetic waves in a periodical structure, scattering matrix representation, eigen excitation, and the design of some guided wave circuits.
The lecture will be focused on the guided wave theory and its application to the design of guided wave circuit in microwave, millimeter-wave and optical regimes. Topics included are electromagnetic wave in waveguides, dispersion in an optical fiber, coupled mode theory, electromagnetic wave in a periodical structure, scattering matrix representation, eigen excitation, and the design of some guided wave circuits.
1.Introduction to waveguide
2.Transmission line
3.Waveguide composed of conductor (coaxial line, micro-strip line, and metallic hollow waveguide)
4.Dielectric waveguide
5.Guided wave in an optical fiber (eigen mode and dispersion)
6.Coupled mode equation
7.Guided waves in periodic structures
8.Scattering matrix
9.Eigen excitation and eigen value
10.Coupled waveguide (directional coupler)
11.Resonators, filter and MUX/DEMUX
12.Nonreciprocal circuits (isolators and circulators)
Text : Download the text from the following web site.
http://mizumoto-www.pe.titech.ac.jp/~tmizumot/lecture_note/guided_wave_circuit_theory/index.html
References :
D.Marcuse, ""Theory of dielectric optical waveguides,"" Academic Press
R.E.Collin, ""Field theory of guided waves,"" McGraw-Hill
J.Helszajn, ""Passive and active microwave circuits,"" John Wiley & Sons
Knowledge of fundamentals on the electromagnetic wave transmission of
undergraduate course are required.
Evaluation will be based on the term end examination.
none
[Office Hours]
Anytime you can visit my office with permission by email at
tmizumotツシpe.titech.ac.jp