"An Introduction to Riemann Geometry 001.ps.gz" - читать интересную книгу автора1 1 2 Lecture Notes An Introduction to Riemannian Geometry (version 1.102 - September 1996) Sigmundur Gudmundsson (Lund University) The latest version of this document can be obtained from: http://www.maths.lth.se/matematiklu/personal/sigma/index.html These lecture notes grew out of an M.Sc.-course on differential geometry which I gave at the University of Leeds 1992. Their main purpose is to introduce the beautiful theory of Riemannian Geometry a still very active area of Mathematics. This is a subject with no lack of interesting examples. They are indeed the key to a good understanding of it and will therefore play a major role throughout this work. Of special interest are the classical Lie groups allowing concrete calculations of many of the abstract notions on the menu. The study of Riemannian Geometry is rather meaningless without some basic knowledge on Gaussian Geometry i.e. the differential geometry of curves and surfaces in Euclidean 3-space. For this we recommend the excellent textbook: M. P. do Carmo, Differential Geometry of Curves and Surfaces, Prentice Hall (1976). These lecture notes are written for students with a good understanding of linear algebra, real analysis of several variables, the classical theory of ODEs and some topology. The most important results stated in the text are also proved there. Other smaller ones are left to the reader as exercises, which follow at the end of each chapter. This format is aimed at students willing to put hard work into the course. It is my intention to extent this very incomplete first draft, which unfortunately still contains typing errors, and include some of the differential geometry of the Riemannian symmetric spaces. For further reading we recommend the very interesting textbook: M. P. do Carmo, Riemannian Geometry, Birkh"auser (1992). Lund University, May 1996 Sigmundur Gudmundsson 2 Contents Chapter 1. Introduction 5 Chapter 2. Differentiable Manifolds 7 Chapter 3. The Tangent Space 15 Chapter 4. The Tangent Bundle 23 Chapter 5. Immersions, Embeddings and Submersions 31 Chapter 6. Riemannian Manifolds 35 Chapter 7. The Levi-Civita Connection 43 Chapter 8. Geodesics 51 Chapter 9. The Curvature Tensor 63 Chapter 10. Curvature and Local Geometry 69 |
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