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Introduction to Smooth Manifolds Second Edition 2012 [Kietas viršelis]

4.46/5 (165 ratings by Goodreads)
  • Formatas: Hardback, 708 pages, aukštis x plotis: 235x155 mm, weight: 1244 g, XVI, 708 p., 1 Hardback
  • Serija: Graduate Texts in Mathematics 218
  • Išleidimo metai: 26-Aug-2012
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 1441999817
  • ISBN-13: 9781441999818
Kitos knygos pagal šią temą:
Introduction to Smooth Manifolds Second Edition 2012Didesnis paveikslėlis
  • Formatas: Hardback, 708 pages, aukštis x plotis: 235x155 mm, weight: 1244 g, XVI, 708 p., 1 Hardback
  • Serija: Graduate Texts in Mathematics 218
  • Išleidimo metai: 26-Aug-2012
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 1441999817
  • ISBN-13: 9781441999818
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9781441999818.html
Raktažodžiai:
This book is an introductory graduate-level textbook on the theory of smooth manifolds. Its goal is to familiarize students with the tools they will need in order to use manifolds in mathematical or scientific research--- smooth structures, tangent vectors and covectors, vector bundles, immersed and embedded submanifolds, tensors, differential forms, de Rham cohomology, vector fields, flows, foliations, Lie derivatives, Lie groups, Lie algebras, and more. The approach is as concrete as possible, with pictures and intuitive discussions of how one should think geometrically about the abstract concepts, while making full use of the powerful tools that modern mathematics has to offer.





This second edition has been extensively revised and clarified, and the topics have been substantially rearranged. The book now introduces the two most important analytic tools, the rank theorem and the fundamental theorem on flows, much earlier so that they can be used throughout the book. A fewnew topics have been added, notably Sards theorem and transversality, a proof that infinitesimal Lie group actions generate global group actions, a more thorough study of first-order partial differential equations, a brief treatment of degree theory for smooth maps between compact manifolds, and an introduction to contact structures.





Prerequisites include a solid acquaintance with general topology, the fundamental group, and covering spaces, as well as basic undergraduate linear algebra and real analysis.

Recenzijos

From the reviews of the second edition:

It starts off with five chapters covering basics on smooth manifolds up to submersions, immersions, embeddings, and of course submanifolds. the book under review is laden with excellent exercises that significantly further the readers understanding of the material, and Lee takes great pains to motivate everything well all the way through . a fine graduate-level text for differential geometers as well as people like me, fellow travelers who always wish they knew more about such a beautiful subject. (Michael Berg, MAA Reviews, October, 2012)

1 Smooth Manifolds
1(31)
Topological Manifolds
2(8)
Smooth Structures
10(7)
Examples of Smooth Manifolds
17(7)
Manifolds with Boundary
24(5)
Problems
29(3)
2 Smooth Maps
32(18)
Smooth Functions and Smooth Maps
32(8)
Partitions of Unity
40(8)
Problems
48(2)
3 Tangent Vectors
50(27)
Tangent Vectors
51(4)
The Differential of a Smooth Map
55(5)
Computations in Coordinates
60(5)
The Tangent Bundle
65(3)
Velocity Vectors of Curves
68(3)
Alternative Definitions of the Tangent Space
71(2)
Categories and Functors
73(2)
Problems
75(2)
4 Submersions, Immersions, and Embeddings
77(21)
Maps of Constant Rank
77(8)
Embeddings
85(3)
Submersions
88(3)
Smooth Covering Maps
91(4)
Problems
95(3)
5 Submanifolds
98(27)
Embedded Submanifolds
98(10)
Immersed Submanifolds
108(4)
Restricting Maps to Submanifolds
112(3)
The Tangent Space to a Submanifold
115(5)
Submanifolds with Boundary
120(3)
Problems
123(2)
6 Sard's Theorem
125(25)
Sets of Measure Zero
125(4)
Sard's Theorem
129(2)
The Whitney Embedding Theorem
131(5)
The Whitney Approximation Theorems
136(7)
Transversality
143(4)
Problems
147(3)
7 Lie Groups
150(24)
Basic Definitions
151(2)
Lie Group Homomorphisms
153(3)
Lie Subgroups
156(5)
Group Actions and Equivariant Maps
161(10)
Problems
171(3)
8 Vector Fields
174(31)
Vector Fields on Manifolds
174(7)
Vector Fields and Smooth Maps
181(4)
Lie Brackets
185(4)
The Lie Algebra of a Lie Group
189(10)
Problems
199(6)
9 Integral Curves and Flows
205(44)
Integral Curves
206(3)
Flows
209(8)
Flowouts
217(5)
Flows and Flowouts on Manifolds with Boundary
222(5)
Lie Derivatives
227(4)
Commuting Vector Fields
231(5)
Time-Dependent Vector Fields
236(3)
First-Order Partial Differential Equations
239(6)
Problems
245(4)
10 Vector Bundles
249(23)
Vector Bundles
249(6)
Local and Global Sections of Vector Bundles
255(6)
Bundle Homomorphisms
261(3)
Subbundles
264(4)
Fiber Bundles
268(1)
Problems
268(4)
11 The Cotangent Bundle
272(32)
Covectors
272(8)
The Differential of a Function
280(4)
Pullbacks of Covector Fields
284(3)
Line Integrals
287(5)
Conservative Covector Fields
292(7)
Problems
299(5)
12 Tensors
304(23)
Multilinear Algebra
305(8)
Symmetric and Alternating Tensors
313(3)
Tensors and Tensor Fields on Manifolds
316(8)
Problems
324(3)
13 Riemannian Metrics
327(22)
Riemannian Manifolds
327(10)
The Riemannian Distance Function
337(4)
The Tangent-Cotangent Isomorphism
341(2)
Pseudo-Riemannian Metrics
343(1)
Problems
344(5)
14 Differential Forms
349(28)
The Algebra of Alternating Tensors
350(9)
Differential Forms on Manifolds
359(3)
Exterior Derivatives
362(11)
Problems
373(4)
15 Orientations
377(23)
Orientations of Vector Spaces
378(2)
Orientations of Manifolds
380(8)
The Riemannian Volume Form
388(4)
Orientations and Covering Maps
392(5)
Problems
397(3)
16 Integration on Manifolds
400(40)
The Geometry of Volume Measurement
401(1)
Integration of Differential Forms
402(9)
Stokes's Theorem
411(4)
Manifolds with Corners
415(6)
Integration on Riemannian Manifolds
421(6)
Densities
427(7)
Problems
434(6)
17 De Rham Cohomology
440(27)
The de Rham Cohomology Groups
441(2)
Homotopy Invariance
443(5)
The Mayer-Vietoris Theorem
448(9)
Degree Theory
457(3)
Proof of the Mayer-Vietoris Theorem
460(4)
Problems
464(3)
18 The de Rham Theorem
467(23)
Singular Homology
467(5)
Singular Cohomology
472(1)
Smooth Singular Homology
473(7)
The de Rham Theorem
480(7)
Problems
487(3)
19 Distributions and Foliations
490(25)
Distributions and Involutivity
491(5)
The Frobenius Theorem
496(5)
Foliations
501(4)
Lie Subalgebras and Lie Subgroups
505(2)
Overdetermined Systems of Partial Differential Equations
507(5)
Problems
512(3)
20 The Exponential Map
515(25)
One-Parameter Subgroups and the Exponential Map
516(6)
The Closed Subgroup Theorem
522(3)
Infinitesimal Generators of Group Actions
525(5)
The Lie Correspondence
530(3)
Normal Subgroups
533(3)
Problems
536(4)
21 Quotient Manifolds
540(24)
Quotients of Manifolds by Group Actions
541(7)
Covering Manifolds
548(2)
Homogeneous Spaces
550(5)
Applications to Lie Theory
555(5)
Problems
560(4)
22 Symplectic Manifolds
564(32)
Symplectic Tensors
565(2)
Symplectic Structures on Manifolds
567(4)
The Darboux Theorem
571(3)
Hamiltonian Vector Fields
574(7)
Contact Structures
581(4)
Nonlinear First-Order PDEs
585(5)
Problems
590(6)
Appendix A Review of Topology
596(21)
Topological Spaces
596(5)
Subspaces, Products, Disjoint Unions, and Quotients
601(6)
Connectedness and Compactness
607(5)
Homotopy and the Fundamental Group
612(3)
Covering Maps
615(2)
Appendix B Review of Linear Algebra
617(25)
Vector Spaces
617(5)
Linear Maps
622(6)
The Determinant
628(7)
Inner Products and Norms
635(3)
Direct Products and Direct Sums
638(4)
Appendix C Review of Calculus
642(21)
Total and Partial Derivatives
642(7)
Multiple Integrals
649(7)
Sequences and Series of Functions
656(1)
The Inverse and Implicit Function Theorems
657(6)
Appendix D Review of Differential Equations
663(12)
Existence, Uniqueness, and Smoothness
663(9)
Simple Solution Techniques
672(3)
References 675(3)
Notation Index 678(5)
Subject Index 683
John M. Lee is Professor of Mathematics at the University of Washington in Seattle, where he regularly teaches graduate courses on the topology and geometry of manifolds. He was the recipient of the American Mathematical Society's Centennial Research Fellowship and he is the author of four previous Springer books: the first edition (2003) of Introduction to Smooth Manifolds, the first edition (2000) and second edition (2010) of Introduction to Topological Manifolds, and Riemannian Manifolds: An Introduction to Curvature (1997).