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Does Gauss's theorem that the Gauss curvature - as computed from the determinant of the differential of the Gauss mapping - is intrinsic, generalize to a hypersurface of a higher dimensional Euclidean space?
mathwonk said:there is a generalization on page 78 of hicks' notes on differential geometry, van nostrand math studies #3, 1965. but there seems to be something special about the case of hypersurfaces of 3 manifolds. see also p. 29.
http://www.wisdom.weizmann.ac.il/~yakov/scanlib/hicks.pdf
The Theorema Egregium, also known as Gauss's Theorem, is a mathematical theorem discovered by Carl Friedrich Gauss in the early 19th century. It states that the curvature of a surface can be determined by measuring the angles and distances on the surface, and it is independent of the way the surface is embedded in space.
Gauss's Theorem can be generalized to higher dimensions and more complex surfaces. This means that the same principle can be applied to curved spaces in higher dimensions, such as 4-dimensional space-time in general relativity.
The Theorema Egregium is significant because it provides a fundamental link between geometry and topology. It also has important applications in physics, specifically in the field of differential geometry and general relativity.
The proof of the Theorema Egregium involves using the notion of Gaussian curvature, which is a measure of the curvature of a surface at a given point. By analyzing the change in Gaussian curvature under different transformations, Gauss was able to prove his theorem.
Yes, the Theorema Egregium has been applied in various fields such as cartography, computer graphics, and physics. It is also used in the study of surfaces and their properties in various branches of mathematics.