phyzguy said:
The external angle theorem, as you have stated it, is only provable if we assume the parallel postulate to be true. So your proposed proof of the parallel postulate is circular.
... answers the original question.
phyzguy said:
When you say "Let's just stick to Euclidean Geometry", this is equivalent to assuming the Parallel Postulate. Euclid assumed the Parallel Postulate to be true. That's why it's called "Euclid
... is the only valid definition here.
jbriggs444 said:
Two lines (in a plane) are "parallel" if they contain no points in common. Given a line and a point not on that line, there are many lines that are "parallel" to the given line and that contain the given point as long as we consider only the local area.
That has nothing to do with the Pythagorean theorem.
... is correct and nothing has to be added.
a-nobody said:
This is your personal right. Fortunately it doesn't change the truth value of what has been said.
Ever since Gauss and his magnificent "Disquisitiones generales circa superficies curvas" the area of the infinitesimal orthogonal triangle on the surface to find the curvature is taken to be: base x height / 2 completely on good terms with the Pythagorean Theorem.
... So? Yes, Gauß worked as a land surveyor. Yes, nobody stated anything else. Yes, this involved non Euclidean geometry. However, non Euclidean geometry is not subject to this thread. Also the term
local is completely inappropriate in this context. It seems that you are talking about some kind of manifolds, in which case some of your assertions might make sense. Unfortunately we deal with a manifold here, which is not only locally Euclidean, but globally. Furthermore we are neither interested in the topology, which is quite boring in a metric Euclidean space, nor in the analysis on it. Our space is globally flat and isomorphic, homeomorphic, diffeomorphic or whatever you like to ##\mathbb{R}^2##, because it is ##\mathbb{R}^2##.
Since the OP's question has been answered and this debate started to create confusion rather than clearance, I close it.
In the case someone of the participants wants to start a discussion on non Euclidean geometries on Riemannian manifolds, please state all given facts at the beginning of a new thread. Here we have a simple Euclidean plane and classic geometry. No add-ons needed.