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Fundamentals of Differential Geometry 1st ed. 1999. Corr. 2nd printing 2001 [Kietas viršelis]

3.86/5 (13 ratings by Goodreads)
  • Formatas: Hardback, 540 pages, aukštis x plotis: 235x155 mm, weight: 2130 g, XVII, 540 p., 1 Hardback
  • Serija: Graduate Texts in Mathematics 191
  • Išleidimo metai: 30-Dec-1998
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 038798593X
  • ISBN-13: 9780387985930
Kitos knygos pagal šią temą:
Fundamentals of Differential Geometry 1st ed. 1999. Corr. 2nd printing 2001Didesnis paveikslėlis
  • Formatas: Hardback, 540 pages, aukštis x plotis: 235x155 mm, weight: 2130 g, XVII, 540 p., 1 Hardback
  • Serija: Graduate Texts in Mathematics 191
  • Išleidimo metai: 30-Dec-1998
  • Leidėjas: Springer-Verlag New York Inc.
  • ISBN-10: 038798593X
  • ISBN-13: 9780387985930
Kitos knygos pagal šią temą:
Pastovi nuoroda: https://www.kriso.lt/db/9780387985930.html
Raktažodžiai:
This book provides an introduction to the basic concepts in differential topology, differential geometry, and differential equations, and some of the main basic theorems in all three areas. This new edition includes new chapters, sections, examples, and exercises.From the reviews: "There are many books on the fundamentals of differential geometry, but this one is quite exceptional; this is not surprising for those who know Serge Lang's books." --EMS NEWSLETTER

This text provides an introduction to basic concepts in differential topology, differential geometry, and differential equations, and some of the main basic theorems in all three areas: for instance, the existence, uniqueness, and smoothness theorems for differential equations and the flow of a vector field; the basic theory of vector bundles including the existence of tubular neighborhoods for a submanifold; the calculus of differential forms; basic notions of symplectic manifolds, including the canonical 2-form; sprays and covariant derivatives for Riemannian and pseudo-Riemannian manifolds; applications to the exponential map, including the Cartan-Hadamard theorem and the first basic theorem of calculus of variations. Although the book grew out of the author's earlier book "Differential and Riemannian Manifolds", the focus has now changed from the general theory of manifolds to general differential geometry, and includes new chapters on Jacobi lifts, tensorial splitting of the double tangent bundle, curvature and the variation formula, a generalization of the Cartan-Hadamard theorem, the semiparallelogram law of Bruhat-Tits and its equivalence with seminegative curvature and the exponential map distance increasing property, a major example of seminegative curvature (the space of positive definite symmetric real matrices), automorphisms and symmetries, and immersions and submersions. These are all covered for infinite-dimensional manifolds, modeled on Banach and Hilbert Spaces, at no cost in complications, and some gain in the elegance of the proofs. In the finite-dimensional case, differential forms of top degree are discussed, leading to Stokes' theorem (even for manifolds with singular boundary), and several of its applications to the differential or Riemannian case. Basic formulas concerning the Laplacian are given, exhibiting several of its features in immersions and submersions.

Recenzijos

"There are many books on the fundamentals of differential geometry, but this one is quite exceptional; this is not surprising for those who know Serge Lang's books. ... It can be warmly recommended to a wide audience." EMS Newsletter, Issue 41, September 2001



"The text provides a valuable introduction to basic concepts and fundamental results in differential geometry. A special feature of the book is that it deals with infinite-dimensional manifolds, modeled on a Banach space in general, and a Hilbert space for Riemannian geometry. The set-up works well on basic theorems such as the existence, uniqueness and smoothness theorem for differential equations and the flow of a vector field, existence of tubular neighborhoods for a submanifold, and the Cartan-Hadamard theorem. A major exception is the Hopf-Rinow theorem. Curvature and basic comparison theorems are discussed. In the finite-dimensional case, volume forms, the Hodge star operator, and integration of differentialforms are expounded. The book ends with the Stokes theorem and some of its applications."-- MATHEMATICAL REVIEWS

Daugiau informacijos

Springer Book Archives
Foreword v(6)
Acknowledgments xi
PART I General Differential Theory 1(170)
CHAPTER 1 Differential Calculus
3(19)
1. Categories
4(1)
2. Topological Vector Spaces
5(3)
3. Derivatives and Composition of Maps
8(4)
4. Integration and Taylor's Formula
12(3)
5. The Inverse Mapping Theorem
15(7)
CHAPTER II Manifolds
22(21)
1. Atlases, Charts, Morphisms
22(3)
2. Submanifolds, Immersions, Submersions
25(8)
3. Partitions of Unity
33(6)
4. Manifolds with Boundary
39(4)
CHAPTER III Vector Bundles
43(23)
1. Definition, Pull Backs
43(8)
2. The Tangent Bundle
51(1)
3. Exact Sequences of Bundles
52(6)
4. Operations on Vector Bundles
58(5)
5. Splitting of Vector Bundles
63(3)
CHAPTER IV Vector Fields and Differential Equations
66(50)
1. Existence Theorem for Differential Equations
67(21)
2. Vector Fields, Curves, and Flows
88(8)
3. Sprays
96(9)
4. The Flow of a Spray and the Exponential Map
105(5)
5. Existence of Tubular Neighborhoods
110(2)
6. Uniqueness of Tubular Neighborhoods
112(4)
CHAPTER V Operations on Vector Fields and Differential Forms
116(39)
1. Vector Fields, Differential Operators, Brackets
116(6)
2. Lie Derivative
122(2)
3. Exterior Derivative
124(13)
4. The Poincare Lemma
137(2)
5. Contractions and Lie Derivative
139(4)
6. Vector Fields and 1-Forms Under Self Duality
143(6)
7. The Canonical 2-Form
149(2)
8. Darboux's Theorem
151(4)
CHAPTER VI The Theorem of Frobenius
155(16)
1. Statement of the Theorem
155(5)
2. Differential Equations Depending on a Parameter
160(1)
3. Proof of the Theorem
161(1)
4. The Global Formulation
162(3)
5. Lie Groups and Subgroups
165(6)
PART II Metrics, Covariant Derivatives, and Riemannian Geometry 171(224)
CHAPTER VII Metrics
173(23)
1. Definition and Functoriality
173(4)
2. The Hilbert Group
177(3)
3. Reduction to the Hilbert Group
180(4)
4. Hilbertian Tubular Neighborhoods
184(2)
5. The Morse-Palais Lemma
186(3)
6. The Riemannian Distance
189(3)
7. The Canonical Spray
192(4)
CHAPTER VIII Covariant Derivatives and Geodesics
196(35)
1. Basic Properties
196(3)
2. Sprays and Covariant Derivatives
199(5)
3. Derivative Along a Curve and Parallelism
204(5)
4. The Metric Derivative
209(6)
5. More Local Results on the Exponential Map
215(6)
6. Riemannian Geodesic Length and Completeness
221(10)
CHAPTER IX Curvature
231(36)
1. The Riemann Tensor
231(8)
2. Jacobi Lifts
239(7)
3. Application of Jacobi Lifts to Texp(x)
246(9)
4. Convexity Theorems
255(8)
5. Taylor Expansions
263(4)
CHAPTER X Jacobi Lifts and Tensorial Splitting of the Double Tangent Bundle
267(27)
1. Convexity of Jacobi Lifts
267(4)
2. Global Tubular Neighborhood of a Totally Geodesic Submanifold
271(5)
3. More Convexity and Comparison Results
276(3)
4. Splitting of the Double Tangent Bundle
279(7)
5. Tensorial Derivative of a Curve in TX and of the Exponential Map
286(5)
6. The Flow and the Tensorial Derivative
291(3)
CHAPTER XI Curvature and the Variation Formula
294(28)
1. The Index Form, Variations, and the Second Variation Formula
294(10)
2. Growth of a Jacobi Lift
304(5)
3. The Semi Parallelogram Law and Negative Curvature
309(6)
4. Totally Geodesic Submanifolds
315(3)
5. Rauch Comparison Theorem
318(4)
CHAPTER XII An Example of Seminegative Curvature
322(17)
1. Pos(n)(R) as a Riemannian Manifold
322(5)
2. The Metric Increasing Property of the Exponential Map
327(5)
3. Totally Geodesic and Symmetric Submanifolds
332(7)
CHAPTER XIII Automorphisms and Symmetries
339(30)
1. The Tensorial Second Derivative
342(5)
2. Alternative Definitions of Killing Fields
347(4)
3. Metric Killing Fields
351(3)
4. Lie Algebra Properties of Killing Fields
354(4)
5. Symmetric Spaces
358(7)
6. Parallelism and the Riemann Tensor
365(4)
CHAPTER XIV Immersions and Submersions
369(26)
1. The Covariant Derivative on a Submanifold
369(7)
2. The Hessian and Laplacian on a Submanifold
376(7)
3. The Covariant Derivative on a Riemannian Submersion
383(4)
4. The Hessian and Laplacian on a Riemannian Submersion
387(3)
5. The Riemann Tensor on Submanifolds
390(3)
6. The Riemann Tensor on a Riemannian Submersion
393(2)
PART III Volume Forms and Integration 395(94)
CHAPTER XV Volume Forms
397(51)
1. Volume Forms and the Divergence
397(10)
2. Covariant Derivatives
407(5)
3. The Jacobian Determinant of the Exponential Map
412(6)
4. The Hodge Star on Forms
418(6)
5. Hodge Decomposition of Differential Forms
424(4)
6. Volume Forms in a Submersion
428(7)
7. Volume Forms on Lie Groups and Homogeneous Spaces
435(5)
8. Homogeneously Fibered Submersions
440(8)
CHAPTER XVI Integration of Differential Forms
448(27)
1. Sets of Measure 0
448(5)
2. Change of Variables Formula
453(8)
3. Orientation
461(2)
4. The Measure Associated with a Differential Form
463(8)
5. Homogeneous Spaces
471(4)
CHAPTER XVII Stokes' Theorem
475(14)
1. Stokes' Theorem for a Rectangular Simplex
475(3)
2. Stokes' Theorem on a Manifold
478(4)
3. Stokes' Theorem with Singularities
482(7)
CHAPTER XVIII Applications of Stokes' Theorem
489(22)
1. The Maximal de Rham Cohomology
489(6)
2. Moser's Theorem
495(1)
3. The Divergence Theorem
496(5)
4. The Adjoint of d for Higher Degree Forms
501(2)
5. Cauchy's Theorem
503(4)
6. The Residue Theorem
507(4)
APPENDIX The Spectral Theorem 511(12)
1. Hilbert Space 511(1)
2. Functionals and Operators 512(3)
3. Hermitian Operators 515(8)
Bibliography 523(8)
Index 531