Modern Geometry - Methods and Applications
Part I: The Geometry of Surfaces, Transformation Groups, and Fields
2nd Edition
Published on 11. November 1991
Book
Hardback
XVI, 470 pages
978-0-387-97663-1 (ISBN)
Description
This is the first volume of a three-volume introduction to modern geometry, with emphasis on applications to other areas of mathematics and theoretical physics. Topics covered include tensors and their differential calculus, the calculus of variations in one and several dimensions, and geometric field theory. This material is explained in as simple and concrete a language as possible, in a terminology acceptable to physicists. The text for the second edition has been substantially revised.
More details
Series
Edition
2nd ed. 1992
Language
English
Place of publication
New York
United States
Target group
Primary & secondary/elementary & high school
Graduate
Edition type
New edition
Illustrations
XVI, 470 p.
Dimensions
Height: 240 mm
Width: 161 mm
Thickness: 32 mm
Weight
900 gr
ISBN-13
978-0-387-97663-1 (9780387976631)
DOI
10.1007/b18400
Schweitzer Classification
Other editions
Additional editions
B.A. Dubrovin | A.T. Fomenko | S.P. Novikov
Modern Geometry - Methods and Applications
Part I: The Geometry of Surfaces, Transformation Groups, and Fields
Book
10/2011
2nd Edition
Springer
€64.15
Shipment within 15-20 days
Previous edition
B. A. Dubrovin
Modern Geometry. Methods and Applications
Part 1: The Geometry of Surfaces, Transformation Groups, and Fields
Book
03/1984
Springer
€55.15
Article exhausted; check for reprint
Persons
Content
1 Geometry in Regions of a Space. Basic Concepts.- §1. Co-ordinate systems.- §2. Euclidean space.- §3. Riemannian and pseudo-Riemannian spaces.- §4. The simplest groups of transformations of Euclidean space.- §5. The Serret-Frenet formulae.- §6. Pseudo-Euclidean spaces.- 2 The Theory of Surfaces.- §7. Geometry on a surface in space.- §8. The second fundamental form.- §9. The metric on the sphere.- §10. Space-like surfaces in pseudo-Euclidean space.- §11. The language of complex numbers in geometry.- §12. Analytic functions.- §13. The conformal form of the metric on a surface.- §14. Transformation groups as surfaces in N-dimensional space.- §15. Conformal transformations of Euclidean and pseudo-Euclidean spaces of several dimensions.- 3 Tensors: The Algebraic Theory.- §16. Examples of tensors.- §17. The general definition of a tensor.- §18. Tensors of type (0, k).- §19. Tensors in Riemannian and pseudo-Riemannian spaces.- §20. The crystallographic groups and the finite subgroups of the rotation group of Euclidean 3-space. Examples of invariant tensors.- §21. Rank 2 tensors in pseudo-Euclidean space, and their eigenvalues.- §22. The behaviour of tensors under mappings.- §23. Vector fields.- §24. Lie algebras.- 4 The Differential Calculus of Tensors.- §25. The differential calculus of skew-symmetric tensors.- §26. Skew-symmetric tensors and the theory of integration.- §27. Differential forms on complex spaces.- §28. Covariant differentiation.- §29. Covariant differentiation and the metric.- §30. The curvature tensor.- 5 The Elements of the Calculus of Variations.- §31. One-dimensional variational problems.- §32. Conservation laws.- §33. Hamiltonian formalism.- §34. The geometrical theory of phase space.- §35. Lagrange surfaces.- §36.The second variation for the equation of the geodesics.- 6 The Calculus of Variations in Several Dimensions. Fields and Their Geometric Invariants.- §37. The simplest higher-dimensional variational problems.- §38. Examples of Lagrangians.- §39. The simplest concepts of the general theory of relativity.- §40. The spinor representations of the groups SO(3) and O(3, 1). Dirac's equation and its properties.- §41. Covariant differentiation of fields with arbitrary symmetry.- §42. Examples of gauge-invariant functionals. Maxwell's equations and the Yang-Mills equation. Functionals with identically zero variational derivative (characteristic classes).