| 000 | 04919nam a22004575i 4500 | ||
|---|---|---|---|
| 001 | 978-1-4614-7867-6 | ||
| 003 | DE-He213 | ||
| 005 | 20140220082830.0 | ||
| 007 | cr nn 008mamaa | ||
| 008 | 130923s2013 xxu| s |||| 0|eng d | ||
| 020 |
_a9781461478676 _9978-1-4614-7867-6 |
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| 024 | 7 |
_a10.1007/978-1-4614-7867-6 _2doi |
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| 050 | 4 | _aQA641-670 | |
| 072 | 7 |
_aPBMP _2bicssc |
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| 072 | 7 |
_aMAT012030 _2bisacsh |
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| 082 | 0 | 4 |
_a516.36 _223 |
| 100 | 1 |
_aGrinfeld, Pavel. _eauthor. |
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| 245 | 1 | 0 |
_aIntroduction to Tensor Analysis and the Calculus of Moving Surfaces _h[electronic resource] / _cby Pavel Grinfeld. |
| 264 | 1 |
_aNew York, NY : _bSpringer New York : _bImprint: Springer, _c2013. |
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| 300 |
_aXIII, 302 p. 37 illus., 4 illus. in color. _bonline resource. |
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| 336 |
_atext _btxt _2rdacontent |
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| 337 |
_acomputer _bc _2rdamedia |
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| 338 |
_aonline resource _bcr _2rdacarrier |
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| 347 |
_atext file _bPDF _2rda |
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| 505 | 0 | _aPreface -- Why Tensor Calculus? -- 1. Rules of the Game -- 2. Coordinate Systems and the Role of Tensor Calculus -- 3. Change of Coordinates -- 4. Tensor Description of Euclidean Spaces -- 5. The Tensor Property -- 6. Covariant Differentiation -- 7. Determinants and the Levi-Civita Symbol -- 8. Tensor Description of Surfaces -- 9. Covariant Derivative of Tensors with Surface Indices -- 10. The Curvature Tensor -- 11. Covariant Derivative of Tensors with Spatial Indices -- 12. Integration and Gauss's Theorem -- 13. Intrinsic Features of Embedded Surfaces -- 14. Further Topics in Differential Geometry -- 15. Classical Problems in the Calculus of Variations -- 16. Equations of Classical Mechanics -- 17. Equations of Continuum Mechanics -- 18. Einstein's Theory of Relativity -- 19. The Rules of Calculus of Moving Surfaces -- 20. Applications of the Calculus of Moving Surfaces. | |
| 520 | _aThis text is meant to deepen its readers’ understanding of vector calculus, differential geometry and related subjects in applied mathematics. Designed for advanced undergraduate and graduate students, this text invites its audience to take a fresh look at previously learned material through the prism of tensor calculus. Once the framework is mastered, the student is introduced to new material which includes differential geometry on manifolds, shape optimization, boundary perturbation, and dynamic fluid film equations. Tensor calculus is a powerful tool that combines the geometric and analytical perspectives and enables us to take full advantage of the computational utility of coordinate systems. The tensor approach can be of benefit to members of all technical sciences including mathematics and all engineering disciplines. If calculus and linear algebra are central to the reader’s scientific endeavors, tensor calculus is indispensable. The language of tensors, originally championed by Einstein, is as fundamental as the languages of calculus and linear algebra and is one that every technical scientist ought to speak. The tensor technique, invented at the turn of the 20th century, is now considered classical. Yet, as the author shows, it remains remarkably vital and relevant. The author’s skilled lecturing capabilities are evident by the inclusion of insightful examples and a plethora of exercises. A great deal of material is devoted to the geometric fundamentals, the mechanics of change of variables, the proper use of the tensor notation, and the discussion of the interplay between algebra and geometry. The early chapters have many words and few equations. The definition of a tensor comes only in Chapter 6 – when the reader is ready for it. While this text maintains a reasonable level of rigor, it takes great care to avoid formalizing the subject. The last part of the textbook is devoted to the calculus of moving surfaces. It is the first textbook exposition of this important technique and is one of the gems of this text. A number of exciting applications of the calculus are presented including shape optimization, boundary perturbation of boundary value problems, and dynamic fluid film equations developed by the author in recent years. Furthermore, the moving surfaces framework is used to offer new derivations of classical results such as the geodesic equation and the celebrated Gauss–Bonnet theorem. | ||
| 650 | 0 | _aMathematics. | |
| 650 | 0 | _aMatrix theory. | |
| 650 | 0 | _aGlobal differential geometry. | |
| 650 | 0 | _aMathematical optimization. | |
| 650 | 1 | 4 | _aMathematics. |
| 650 | 2 | 4 | _aDifferential Geometry. |
| 650 | 2 | 4 | _aCalculus of Variations and Optimal Control; Optimization. |
| 650 | 2 | 4 | _aLinear and Multilinear Algebras, Matrix Theory. |
| 710 | 2 | _aSpringerLink (Online service) | |
| 773 | 0 | _tSpringer eBooks | |
| 776 | 0 | 8 |
_iPrinted edition: _z9781461478669 |
| 856 | 4 | 0 | _uhttp://dx.doi.org/10.1007/978-1-4614-7867-6 |
| 912 | _aZDB-2-SMA | ||
| 999 |
_c95998 _d95998 |
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