高斯曲率的布里奥斯奇公式

arXiv - MATH - History and Overview Pub Date : 2024-04-01 DOI:arxiv-2404.00835

Lee-Peng Teo

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引用次数: 0

摘要

布里俄斯基公式用曲面$S$局部坐标中的函数$E、F$和$G$来表示高斯曲率$K$。这意味着高斯的egregium定理，即高斯曲率只取决于角度、距离及其变化率。在大多数教科书中，高斯定理都是作为推导高斯方程的必然结果来证明的，高斯方程是一组用克里斯托弗符号表示 $EK、FK$ 和 $GK$ 的方程。克里斯托弗符号可以用 $E$、$F$ 和 $G$ 表示。原则上，经过一些繁琐的计算，我们可以从高斯方程推导出布里俄斯基公式。在本说明中，我们给出了布里俄斯基公式的直接基本证明，而无需使用克里斯托弗符号。证明的关键是矩阵和行列式的性质。

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The Brioschi Formula for the Gaussian Curvature

The Brioschi formula expresses the Gaussian curvature $K$ in terms of the functions $E, F$ and $G$ in local coordinates of a surface $S$. This implies the Gauss' theorema egregium, which says that the Gaussian curvature just depends on angles, distances, and their rates of change. In most of the textbooks, the Gauss' theorema egregium was proved as a corollary to the derivation of the Gauss equations, a set of equations expressing $EK, FK$ and $GK$ in terms of the Christoffel symbols. The Christoffel symbols can be expressed in terms of $E$, $F$ and $G$. In principle, one can derive the Brioschi formula from the Gauss equations after some tedious calculations. In this note, we give a direct elementary proof of the Brioschi formula without using Christoffel symbols. The key to the proof are properties of matrices and determinants.

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arXiv - MATH - History and Overview

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