+svend stormeyer I'm glad you enjoyed it. We have fun here making them.

On a perfect conductor yes. In fact a mirror is a conductor (a thin film of silver on the surface which reflects the light which is an electromagnetic wave). The losses he talks is mainly due to the fact that wave guides aren't perfect conductors, so this "no infinite conductivity" produces heat losses due to Joule effect: work done by the electric field to push charges on the conductor. To study the reflection of a medium one has to look por the impedancies, on a perfect conductor it is infinite so all EM reflects on a perfect conductor (gamma = -1).

General linear combinations of TE, TM AND TEM modes. The most general polarization is the elliptic one, circular and linear are just specific cases.

Primarily, they are both metal high-pass filters made of hollow metal. The difference is mainly that circular waveguides operate in TE11, and rectangular ones operate in TE10.

Highly conductive materials are used to construct waveguides. For rigid waveguides, these are metals that can be extruded in order to produce them inexpensively. Aluminum is common for this. Copper and brass are also common when building flexible waveguides. Rather than smooth walls, these are generally transverse corrugated structures that allow the material to flex for the application. Surface conductivity is what matters. You can use a plastic tube with a conductive surface layer of gold, nickel, or silver as well.

Not at this time, but this could certainly be done. Is there a particular aspect that you would like highlighted?

This is a nice way to interact with the concepts www.wolframalpha.com/input/?i=waveguide

Much appreciated!

Thank you! Are there any other topics that you would like to see covered?

+Daniel Rogers yea sir .. please explain transmission lines..and their different formulae.