Eberhard Malkowsky (Serbia University of Nis), Cemal Dolicanin, Vesna Velickovic
Differential Geometry and Its Visualization
Eberhard Malkowsky (Serbia University of Nis), Cemal Dolicanin, Vesna Velickovic
Differential Geometry and Its Visualization
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This book is suitable for graduate level courses in differential geometry, serving both students and teachers. It can also be used as a supplementary reference for research in mathematics and the natural and engineering sciences.
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This book is suitable for graduate level courses in differential geometry, serving both students and teachers. It can also be used as a supplementary reference for research in mathematics and the natural and engineering sciences.
Produktdetails
- Produktdetails
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 466
- Erscheinungstermin: 30. August 2023
- Englisch
- Abmessung: 254mm x 178mm x 27mm
- Gewicht: 1192g
- ISBN-13: 9781032436661
- ISBN-10: 1032436662
- Artikelnr.: 67822631
- Verlag: Taylor & Francis Ltd
- Seitenzahl: 466
- Erscheinungstermin: 30. August 2023
- Englisch
- Abmessung: 254mm x 178mm x 27mm
- Gewicht: 1192g
- ISBN-13: 9781032436661
- ISBN-10: 1032436662
- Artikelnr.: 67822631
Eberhard Malkowsky is a Full Professor of Mathematics in retirement at the State University of Novi Pazar in Serbia. He earned his Ph.D. degree and habilitation at the Department of Mathematics of the Justus-Liebig Universität Giessen in Germany in 1982 and 1988, respectively. He was a professor of mathematics at universities in Germany, South Africa, Jordan, Turkey and Serbia, and a visiting professor in the USA, India, Hungary and France. Furthermore, he participated as an invited or keynote speaker with more than 100 lectures in international scientific conferences and congresses. He is a member of the editorial boards of twelve journals of international repute. His list of publications contains 175 research papers in international journals. He is the author or co-author of nine books, and the editor or co-editor of six proceedings of international conferences. He supervised 6 Ph.D. theses and a great number of B.Sc. and M.Sc. theses in mathematics. His research and work areas include functional analysis, differential geometry and software development for the visualization of mathematics. ¿emal Doli¿anin is a Professor Emeritus at the Department of Sciences and Mathematics at the State University of Novi Pazar in Serbia and a member of the Serbian Academy of Non-linear Sciences. He was dean of the Electro-Technical Faculty and the Faculty of Technical Sciences in Pritina, vice-rector of the University of Pritina and founder and rector of the State University of Novi Pazar, Serbia. He obtained his M.Sc. degree at the Faculty of Mathematics of the University of Belgrade in 1974, and his Ph.D. degree at the Faculty of Sciences and Mathematics of the University of Pritina in 1980. He published more than 20 books, 23 papers in national scientific journals, 41 papers in international scientific journals, and gave more than 50 lectures at international scientific conferences. He was a visiting professor in Germany, Belorussia and Russia. He supervised 14 PhD theses and a great number of B.Sc. and M.Sc. theses in mathematics. His research and work areas include Euclidean and non-Euclidean geometry, differential geometry and applied mathematics. He is very active in promoting mathematics, and has established the Center for the Advancement and Popularization of Mathematics at the State University of Novi Pazar. He participated in the implementation of several national scientific projects TEMPUS projects and was the coordinator of Master's study programs with the World University Service Austria (WUS). Vesna Veli¿kovi¿ is a Professor at the Department of Computer Science at the Faculty of Sciences and Mathematics of the University of Ni, Serbia. She obtained her magister degree at the Faculty of Mathematics of the University of Belgrade in 1996, and her Ph.D. degree at the Faculty of Sciences and Mathematics of the University of Ni in 2012. She published 3 books, 30 papers in international scientific journals, 12 papers in national scientific journals, and gave more than 50 lectures at international scientific conferences. She participated in 3 international scientific and 4 software projects, and 7 study visits in Serbia, Germany, Bulgaria, Romania and Turkey. Together with Professor Malkowsky, she is developing the software MV-Graphics for visualization of mathematics. With large-format graphics, they participated in three exhibitions of mathematical art. For ten years she worked with pupils talented in mathematics and programming. Her students won a number of medals at International Olympiads in Informatics. She is still very active in organizing contests in programming and promoting of mathematics. Her research areas are software development, computer graphics and visualization of mathematics.
1. Curves in Three-dimensional Euclidean Space. 1.1. Points and Vectors.
1.2. Vector-valued Functions of a Real Variable. 1.3. The General Concept
of Curves. 1.4. Some Examples of Planar Curves. 1.5. The Arc Length of a
Curve. 1.6. The Vectors of the Trihedron of a Curve. 1.7. Frenet's
Formulae. 1.8. The Geometric Significance of Curvature and Torsion. 1.9.
Osculating Circles and Spheres. 1.10. Involutes and Evolutes. 1.11. The
Fundamental Theorem of Curves. 1.12. Lines of Constant Slope. 1.13.
Spherical Images of a Curve. 2. Surfaces in Three-dimensional Euclidean
Space. 2.1. Surfaces and Curves on Surfaces. 2.2. The Tangent Planes and
Normal Vectors of a Surface. 2.3. The Arc Length, Angles and Gauss's First
Fundamental Coefficients. 2.4. the Curvature of Curves on Surfaces,
Geodesic and Normal Curvature. 2.5. The Normal, Principal, Gaussian and
Mean Curvature. 2.6. The Shape of a Surface in the Neighbourhood of a
Point. 2.7. Dupin's Indicatrix. 2.8. Lines of Curvature and Asymptotic
Lines. 2.9. Triple Orthogonal Systems. 2.10. the Weingarten Equations. 3.
The Intrinsic Geometry of Surfaces. 3.1. the Christoffel Symbols. 3.2.
Geodesic Lines. 3.3. Geodesic Lines on Surfaces with Orthogonal Parameters.
3.4. Geodesic Lines on Surfaces of Revolution. 3.5. the Minimum Property of
Geodesic Lines. 3.6. Orthogonal and Geodesic Parameters. 3.7. Levi-civitá
Parallelism. 3.8. Theorema Egregium. 3.9. Maps Between Surfaces. 3.10. the
Gauss-bonnet Theorem. 3.11. Minimal Surfaces. 4. Tensor Algebra and
Riemannian Geometry. 4.1. Differentiable Manifolds. 4.2. Transformation of
Bases. 4.3. Linear Functionals and Dual Spaces. 4.4. Tensors of Second
Order. 4.5. Symmetric Bilinear Forms and Inner Products. 4.6. Tensors of
Arbitary Order. 4.7. Symmetric and Anti-symmetric Tensors. 4.8. Riemann
Spaces. 4.9. the Christoffel Symbols. 5. Tensor Analysis. 5.1. Covariant
Differentiation. 5.2. the Covariant Derivative of an (R, S)-tensor. 5.3.
the Interchange of Order for Covariant Differentiation and Ricci's
Identity. 5.4. Bianchi's Identities for the Covariant Derivative of the
Tensors of Curvature. 5.5. Beltrami's Differentiators. 5.6. a Geometric
Meaning of the Covariant Differentiation, the Levi-civitá Parallelism. 5.7.
The Fundamental Theorem for Surfaces. 5.8. A Geometric Meaning of the
Riemann Tensor of Curvature. 5.9. Spaces With Vanishing Tensor of
Curvature. 5.10. An Extension of Frenet's Formulae. 5.11. Riemann Normal
Coordinates and the Curvature of Spaces.
1.2. Vector-valued Functions of a Real Variable. 1.3. The General Concept
of Curves. 1.4. Some Examples of Planar Curves. 1.5. The Arc Length of a
Curve. 1.6. The Vectors of the Trihedron of a Curve. 1.7. Frenet's
Formulae. 1.8. The Geometric Significance of Curvature and Torsion. 1.9.
Osculating Circles and Spheres. 1.10. Involutes and Evolutes. 1.11. The
Fundamental Theorem of Curves. 1.12. Lines of Constant Slope. 1.13.
Spherical Images of a Curve. 2. Surfaces in Three-dimensional Euclidean
Space. 2.1. Surfaces and Curves on Surfaces. 2.2. The Tangent Planes and
Normal Vectors of a Surface. 2.3. The Arc Length, Angles and Gauss's First
Fundamental Coefficients. 2.4. the Curvature of Curves on Surfaces,
Geodesic and Normal Curvature. 2.5. The Normal, Principal, Gaussian and
Mean Curvature. 2.6. The Shape of a Surface in the Neighbourhood of a
Point. 2.7. Dupin's Indicatrix. 2.8. Lines of Curvature and Asymptotic
Lines. 2.9. Triple Orthogonal Systems. 2.10. the Weingarten Equations. 3.
The Intrinsic Geometry of Surfaces. 3.1. the Christoffel Symbols. 3.2.
Geodesic Lines. 3.3. Geodesic Lines on Surfaces with Orthogonal Parameters.
3.4. Geodesic Lines on Surfaces of Revolution. 3.5. the Minimum Property of
Geodesic Lines. 3.6. Orthogonal and Geodesic Parameters. 3.7. Levi-civitá
Parallelism. 3.8. Theorema Egregium. 3.9. Maps Between Surfaces. 3.10. the
Gauss-bonnet Theorem. 3.11. Minimal Surfaces. 4. Tensor Algebra and
Riemannian Geometry. 4.1. Differentiable Manifolds. 4.2. Transformation of
Bases. 4.3. Linear Functionals and Dual Spaces. 4.4. Tensors of Second
Order. 4.5. Symmetric Bilinear Forms and Inner Products. 4.6. Tensors of
Arbitary Order. 4.7. Symmetric and Anti-symmetric Tensors. 4.8. Riemann
Spaces. 4.9. the Christoffel Symbols. 5. Tensor Analysis. 5.1. Covariant
Differentiation. 5.2. the Covariant Derivative of an (R, S)-tensor. 5.3.
the Interchange of Order for Covariant Differentiation and Ricci's
Identity. 5.4. Bianchi's Identities for the Covariant Derivative of the
Tensors of Curvature. 5.5. Beltrami's Differentiators. 5.6. a Geometric
Meaning of the Covariant Differentiation, the Levi-civitá Parallelism. 5.7.
The Fundamental Theorem for Surfaces. 5.8. A Geometric Meaning of the
Riemann Tensor of Curvature. 5.9. Spaces With Vanishing Tensor of
Curvature. 5.10. An Extension of Frenet's Formulae. 5.11. Riemann Normal
Coordinates and the Curvature of Spaces.
1. Curves in Three-dimensional Euclidean Space. 1.1. Points and Vectors.
1.2. Vector-valued Functions of a Real Variable. 1.3. The General Concept
of Curves. 1.4. Some Examples of Planar Curves. 1.5. The Arc Length of a
Curve. 1.6. The Vectors of the Trihedron of a Curve. 1.7. Frenet's
Formulae. 1.8. The Geometric Significance of Curvature and Torsion. 1.9.
Osculating Circles and Spheres. 1.10. Involutes and Evolutes. 1.11. The
Fundamental Theorem of Curves. 1.12. Lines of Constant Slope. 1.13.
Spherical Images of a Curve. 2. Surfaces in Three-dimensional Euclidean
Space. 2.1. Surfaces and Curves on Surfaces. 2.2. The Tangent Planes and
Normal Vectors of a Surface. 2.3. The Arc Length, Angles and Gauss's First
Fundamental Coefficients. 2.4. the Curvature of Curves on Surfaces,
Geodesic and Normal Curvature. 2.5. The Normal, Principal, Gaussian and
Mean Curvature. 2.6. The Shape of a Surface in the Neighbourhood of a
Point. 2.7. Dupin's Indicatrix. 2.8. Lines of Curvature and Asymptotic
Lines. 2.9. Triple Orthogonal Systems. 2.10. the Weingarten Equations. 3.
The Intrinsic Geometry of Surfaces. 3.1. the Christoffel Symbols. 3.2.
Geodesic Lines. 3.3. Geodesic Lines on Surfaces with Orthogonal Parameters.
3.4. Geodesic Lines on Surfaces of Revolution. 3.5. the Minimum Property of
Geodesic Lines. 3.6. Orthogonal and Geodesic Parameters. 3.7. Levi-civitá
Parallelism. 3.8. Theorema Egregium. 3.9. Maps Between Surfaces. 3.10. the
Gauss-bonnet Theorem. 3.11. Minimal Surfaces. 4. Tensor Algebra and
Riemannian Geometry. 4.1. Differentiable Manifolds. 4.2. Transformation of
Bases. 4.3. Linear Functionals and Dual Spaces. 4.4. Tensors of Second
Order. 4.5. Symmetric Bilinear Forms and Inner Products. 4.6. Tensors of
Arbitary Order. 4.7. Symmetric and Anti-symmetric Tensors. 4.8. Riemann
Spaces. 4.9. the Christoffel Symbols. 5. Tensor Analysis. 5.1. Covariant
Differentiation. 5.2. the Covariant Derivative of an (R, S)-tensor. 5.3.
the Interchange of Order for Covariant Differentiation and Ricci's
Identity. 5.4. Bianchi's Identities for the Covariant Derivative of the
Tensors of Curvature. 5.5. Beltrami's Differentiators. 5.6. a Geometric
Meaning of the Covariant Differentiation, the Levi-civitá Parallelism. 5.7.
The Fundamental Theorem for Surfaces. 5.8. A Geometric Meaning of the
Riemann Tensor of Curvature. 5.9. Spaces With Vanishing Tensor of
Curvature. 5.10. An Extension of Frenet's Formulae. 5.11. Riemann Normal
Coordinates and the Curvature of Spaces.
1.2. Vector-valued Functions of a Real Variable. 1.3. The General Concept
of Curves. 1.4. Some Examples of Planar Curves. 1.5. The Arc Length of a
Curve. 1.6. The Vectors of the Trihedron of a Curve. 1.7. Frenet's
Formulae. 1.8. The Geometric Significance of Curvature and Torsion. 1.9.
Osculating Circles and Spheres. 1.10. Involutes and Evolutes. 1.11. The
Fundamental Theorem of Curves. 1.12. Lines of Constant Slope. 1.13.
Spherical Images of a Curve. 2. Surfaces in Three-dimensional Euclidean
Space. 2.1. Surfaces and Curves on Surfaces. 2.2. The Tangent Planes and
Normal Vectors of a Surface. 2.3. The Arc Length, Angles and Gauss's First
Fundamental Coefficients. 2.4. the Curvature of Curves on Surfaces,
Geodesic and Normal Curvature. 2.5. The Normal, Principal, Gaussian and
Mean Curvature. 2.6. The Shape of a Surface in the Neighbourhood of a
Point. 2.7. Dupin's Indicatrix. 2.8. Lines of Curvature and Asymptotic
Lines. 2.9. Triple Orthogonal Systems. 2.10. the Weingarten Equations. 3.
The Intrinsic Geometry of Surfaces. 3.1. the Christoffel Symbols. 3.2.
Geodesic Lines. 3.3. Geodesic Lines on Surfaces with Orthogonal Parameters.
3.4. Geodesic Lines on Surfaces of Revolution. 3.5. the Minimum Property of
Geodesic Lines. 3.6. Orthogonal and Geodesic Parameters. 3.7. Levi-civitá
Parallelism. 3.8. Theorema Egregium. 3.9. Maps Between Surfaces. 3.10. the
Gauss-bonnet Theorem. 3.11. Minimal Surfaces. 4. Tensor Algebra and
Riemannian Geometry. 4.1. Differentiable Manifolds. 4.2. Transformation of
Bases. 4.3. Linear Functionals and Dual Spaces. 4.4. Tensors of Second
Order. 4.5. Symmetric Bilinear Forms and Inner Products. 4.6. Tensors of
Arbitary Order. 4.7. Symmetric and Anti-symmetric Tensors. 4.8. Riemann
Spaces. 4.9. the Christoffel Symbols. 5. Tensor Analysis. 5.1. Covariant
Differentiation. 5.2. the Covariant Derivative of an (R, S)-tensor. 5.3.
the Interchange of Order for Covariant Differentiation and Ricci's
Identity. 5.4. Bianchi's Identities for the Covariant Derivative of the
Tensors of Curvature. 5.5. Beltrami's Differentiators. 5.6. a Geometric
Meaning of the Covariant Differentiation, the Levi-civitá Parallelism. 5.7.
The Fundamental Theorem for Surfaces. 5.8. A Geometric Meaning of the
Riemann Tensor of Curvature. 5.9. Spaces With Vanishing Tensor of
Curvature. 5.10. An Extension of Frenet's Formulae. 5.11. Riemann Normal
Coordinates and the Curvature of Spaces.