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--- basic_tools:pythagorean_theorem [2018/03/27 16:28]
jakobadmin [Why is it interesting?]
+++ basic_tools:pythagorean_theorem [2018/05/06 14:01]
ida [Abstract]
@@ Line 10: / Line 10: @@
 <tabbox Abstract>
-<note tip>
+<blockquote>
-The motto in this section is: //the higher the level of abstraction, the better//.
-</note>
+Pythagoras’s Theorem,
+$$(ds)^2 = (dx)^2 + (dy)^2 $$
+Riemann realized some fundamental things:
+  - Pythagoras’s Theorem not only told of the properties of right-angled triangles, but the function $(ds)$ (the positive square root of $(ds)^2$), was the ‘distance’ between two points;
+  - (ii) more than that, it was the shortest ‘distance’ between two points;
+  - (iii) most amazing of all, Pythagoras’s $(ds)^2$ was but one possibility - more generally, it could be written as:
+$$(ds)^2 = g_{xx}(dx)(dx) + +g_{xy}(dx)(dy) + g_{yx}(dy)(dx) + g_{yy}(dy)(dy) ,$$
+where the $g_{ij}$ are coefficients to be determined. In Pythagoras’s Theorem, it just so happens that we have the values $g_{xx}=1$, $g_{xy}=0$, $g_{yx}=0$, and $g_{yy}=1$.
+In other cases (other spaces),the $g_{ij}$ need not have these particular values, and need not be constants - they could even be functions of x and y. This discussion has, so far, been in a space of only two dimensions, but Riemann generalized his ‘distance function’ still further to n dimensions.
+<cite>The Lazy Universe by Coopersmith</cite>
+</blockquote>
 <tabbox Why is it interesting?>