Deriving the Fresnel Equations for E Field in Plane of Incidence

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The discussion focuses on deriving the Fresnel equations for the electric field perpendicular to the plane of incidence. The original poster is struggling with a specific mathematical transformation referenced in an external link, which combines two equations to achieve the Fresnel equation. Another participant confirms the link works for them but cannot assist further and inquires about the class context. The conversation highlights the challenge of understanding the mathematical steps involved in the derivation. Overall, the thread emphasizes the need for clarification on the mathematical process to derive the Fresnel equations.
Cummings
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I am trying to derive the Fresnel equations for the E field perpendicular to the plane of incidence.

There is one transformation, I assume involves some general math, that I am having a mental blank on.

It can be found here http://physics.tamuk.edu/~suson/html/4323/prop-em.html if you scroll down to Equation 7.17, they simply state that combining it with Equation 7.14 you can achieve 7.18, the fresnel equation.

I assuming this is just some substitution and re araging but for the life of me I am unable to figure out how they did. it.

Enlighten me.
________
Cummings
BSc: Photonics
BEng: Telecommunications and Internet Technologies.
 
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I can't open that link. Will you double-check ?
 
Gokul43201 said:
I can't open that link. Will you double-check ?

hmm.. the link works for me.


sorry, can't help ya, but may i ask, what class is this for? EM II or optics or something? fairly interesting.
 

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