Topology and its applications
著者
書誌事項
Topology and its applications
(Pure and applied mathematics)
John Wiley & Sons, c2006
- : hbk
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注記
"Wiley-Interscience."
Includes bibliographical references (p. 333-336) and index
内容説明・目次
内容説明
Discover a unique and modern treatment of topology employing a cross-disciplinary approach Implemented recently to understand diverse topics, such as cell biology, superconductors, and robot motion, topology has been transformed from a theoretical field that highlights mathematical theory to a subject that plays a growing role in nearly all fields of scientific investigation. Moving from the concrete to the abstract, Topology and Its Applications displays both the beauty and utility of topology, first presenting the essentials of topology followed by its emerging role within the new frontiers in research.
Filling a gap between the teaching of topology and its modern uses in real-world phenomena, Topology and Its Applications is organized around the mathematical theory of topology, a framework of rigorous theorems, and clear, elegant proofs.
This book is the first of its kind to present applications in computer graphics, economics, dynamical systems, condensed matter physics, biology, robotics, chemistry, cosmology, material science, computational topology, and population modeling, as well as other areas of science and engineering. Many of these applications are presented in optional sections, allowing an instructor to customize the presentation.
The author presents a diversity of topological areas, including point-set topology, geometric topology, differential topology, and algebraic/combinatorial topology. Topics within these areas include:
Open sets
Compactness
Homotopy
Surface classification
Index theory on surfaces
Manifolds and complexes
Topological groups
The fundamental group and homology
Special "core intuition" segments throughout the book briefly explain the basic intuition essential to understanding several topics. A generous number of figures and examples, many of which come from applications such as liquid crystals, space probe data, and computer graphics, are all available from the publisher's Web site.
目次
Preface. Introduction.
I. 1 Preliminaries.
1.2 Cardinality.
1. Continuity.
1. 1 Continuity and Open Sets in Rn.
1.2 Continuity and Open Sets in Topological Spaces.
1.3 Metric, Product, and Quotient Topologies.
1.4 Subsets of Topological Spaces.
1.5 Continuous Functions and Topological Equivalence.
1.6 Surfaces.
1.7 Application: Chaos in Dynamical Systems.
1.7.1 History of Chaos.
1.7.2 A Simple Example.
1.7.3 Notions of Chaos.
2. Compactness and Connectedness.
2.1 Closed Bounded Subsets of R.
2.2 Compact Spaces.
2.3 Identification Spaces and Compactness.
2.4 Connectedness and path-connectedness.
2.5 Cantor Sets.
2.6 Application: Compact Sets in Population Dynamics and Fractals.
3. Manifolds and Complexes.
3.1 Manifolds.
3.2 Triangulations.
3.3 Classification of Surfaces.
3.3.1 Gluing Disks.
3.3.2 Planar Models.
3.3.3 Classification of Surfaces.
3.4 Euler Characteristic.
3.5 Topological Groups.
3.6 Group Actions and Orbit Spaces.
3.6.1 Flows on Tori.
3.7 Applications.
3.7.1 Robotic Coordination and Configuration Spaces.
3.7.2 Geometry of Manifolds.
3.7.3 The Topology of the Universe.
4. Homotopy and the Winding Number.
4.1 Homotopy and Paths.
4.2 The Winding Number.
4.3 Degrees of Maps.
4.4 The Brouwer Fixed Point Theorem.
4.5 The Borsuk-Ulam Theorem.
4.6 Vector Fields and the Poincare' Index Theorem.
4.7 Applications I.
4.7.1 The Fundamental Theorem of Algebra.
4.7.2 Sandwiches.
4.7.3 Game Theory and Nash Equilibria.
4.8 Applications 1I: Calculus.
4.8.1 Vector Fields, Path Integrals, and the Winding Number.
4.8.2 Vector Fields on Surfaces.
4.8.3 1ndex Theory for n-Symmetry Fields.
4.9 Index Theory in Computer Graphics.
5. Fundamental Group.
5. I Definition and Basic Properties.
5.2 Homotopy Equivalence and Retracts.
5.3 The Fundamental Group of Spheres and Tori.
5.4 The Seifert-van Kampen Theorem.
5.4.1 Flowers and Surfaces.
5.4.2 The Seifert-van Kampen Theorem.
5.5 Covering spaces.
5.6 Group Actions and Deck Transformations.
5.7 Applications.
5.7.1 Order and Emergent Patterns in Condensed Matter Physics.
6. Homology.
6.1 A-complexes.
6.2 Chains and Boundaries.
6.3 Examples and Computations.
6.4 Singular Homology.
6.5 Homotopy Invariance.
6.6 Brouwer Fixed Point Theorem for Dn.
6.7 Homology and the Fundamental Group.
6.8 Betti Numbers and the Euler Characteristic.
6.9 Computational Homology.
6.9.1 Computing Betti Numbers.
6.9.2 Building a Filtration.
6.9.3 Persistent Homology.
Appendix A: Knot Theory.
Appendix B: Groups.
Appendix C: Perspectives in Topology.
C.1 Point Set Topology.
C.2 Geometric Topology.
C.3 Algebraic Topology.
C.4 Combinatorial Topology.
C.5 Differential Topology.
References.
Bibliography.
Index.
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