Purchase textbook

Curves and Surfaces in Geometric Modeling,

Edition 1 Theory & Algorithms

Editors: By Jean Gallier

Publication Date: 21 Oct 1999

0 Reviews

Ways Of Reading

This e-publication is accessible to the full extent that the file format and types of content allow, on a specific reading device, by default, without necessarily including any additions such as textual descriptions of images or enhanced navigation.

Navigation

The contents of the PDF have been tagged to permit access by assistive technologies as per PDF-UA-1 standard.
Page breaks included from the original print source

Additional Accessibility Information

All (or substantially all) textual matter is arranged in a single logical reading order (including text that is visually presented as separate from the main text flow, e.g., in boxouts, captions, tables, footnotes, endnotes, citations, etc.). Non-textual content is also linked from within this logical reading order. (Purely decorative non-text content can be ignored).
The language of the text has been specified (e.g., via the HTML or XML lang attribute) to optimise text-to-speech (and other alternative renderings), both at the whole document level and, where appropriate, for individual words, phrases or passages in a different language.

Conformance

The publication was certified on 20250728
Accessibility addendum
For detailed accessibility information, see Elsevier’s website at https://www.elsevier.com/about/accessibility
For queries regarding accessibility information, contact [email protected]

Note

This product relies on 3rd party tooling which may impact the accessibility features visible in inspection copies. All accessibility features mentioned would be present in the purchased version of the title.

Curves and Surfaces for Geometric Design offers both a theoretically unifying understanding of polynomial curves and surfaces and an effective approach to implementation that you can bring to bear on your own work—whether you're a graduate student, scientist, or practitioner.

Inside, the focus is on "blossoming"—the process of converting a polynomial to its polar form—as a natural, purely geometric explanation of the behavior of curves and surfaces. This insight is important for far more than its theoretical elegance, for the author proceeds to demonstrate the value of blossoming as a practical algorithmic tool for generating and manipulating curves and surfaces that meet many different criteria. You'll learn to use this and related techniques drawn from affine geometry for computing and adjusting control points, deriving the continuity conditions for splines, creating subdivision surfaces, and more.

The product of groundbreaking research by a noteworthy computer scientist and mathematician, this book is destined to emerge as a classic work on this complex subject. It will be an essential acquisition for readers in many different areas, including computer graphics and animation, robotics, virtual reality, geometric modeling and design, medical imaging, computer vision, and motion planning.

Key Features

* Achieves a depth of coverage not found in any other book in this field.* Offers a mathematically rigorous, unifying approach to the algorithmic generation and manipulation of curves and surfaces. * Covers basic concepts of affine geometry, the ideal framework for dealing with curves and surfaces in terms of control points.* Details (in Mathematica) many complete implementations, explaining how they produce highly continuous curves and surfaces.* Presents the primary techniques for creating and analyzing the convergence of subdivision surfaces (Doo-Sabin, Catmull-Clark, Loop).* Contains appendices on linear algebra, basic topology, and differential calculus.

About the author

By Jean Gallier

1 Introduction1.1 Geometric Methods in Engineering1.2 Examples of Problems Using Geometric Modeling2 Basics of Affine Geometry 2.1 Affine Spaces2.2 Examples of Affine Spaces2.3 Chasles' Identity2.4 Affine Combinations, Barycenters2.5 Affine Subspaces2.6 Affine Independence and Affine Frames2.7 Affine Maps2.8 Affine Groups2.9 Affine Hyperplanes3 Introduction to the Algorithmic Geometry of Polynomial Curves3.1 Why Parameterized Polynomial Curves?3.2 Polynomial Curves of degree 1 and 23.3 First Encounter with Polar Forms (Blossoming)3.4 First Encounter with the de Casteljau Algorithm3.5 Polynomial Curves of Degree 33.6 Classification of the Polynomial Cubics3.7 Second Encounter with Polar Forms (Blossoming)3.8 Second Encounter with the de Casteljau Algorith3.9 Examples of Cubics Defined by Control Points4 Multiaffine Maps and Polar Forms4.1 Multiaffine Maps4.2 Affine Polynomials and Polar Forms4.3 Polynomial Curves and Control Points4.4 Uniqueness of the Polar Form of an Affine Polynomial Map4.5 Polarizing Polynomials in One or Several Variables5 Polynomial Curves as Be'zier Curves5.1 The de Casteljau Algorithm5.2 Subdivision Algorithms for Polynomial Curves5.3 The Progressive Version of the de Casteljau Algorithm (the de Boor Algorithm)5.4 Derivatives of Polynomial Curves5.5 Joining Affine Polynomial Functions6 B-Spline Curves6.1 Introduction: Knot Sequences, de Boor Control Points6.2 Infinite Knot Sequences, Open B-Spline Curves6.3 Finite Knot Sequences, Finite B-Spline Curves6.4 Cyclic Knot Sequences, Closed (Cyclic) B-Spline Curves6.5 The de Boor Algorithm6.6 The de Boor Algorithm and Knot Insertion6.7 Polar forms of B-Splines6.8 Cubic Spline Interpolation7 Polynomial Surfaces7.1 Polarizing Polynomial Surfaces7.2 Bipolynomial Surfaces in Polar Form7.3 The de Casteljau Algorithm for Rectangular Surface Patches7.4 Total Degree Surfaces in Polar Form7.5 The de Casteljau Algorithm for Triangular Surface Patches7.6 Directional Derivatives of Polynomial Surfaces8 Subdivision Algorithms for Polynomial Surfaces 2948.1 Subdivision Algorithms for Triangular Patches8.2 Subdivision Algorithms for Rectangular Patches9. Polynomial Spline Surfaces and Subdivision Surfaces9.1 Joining Polynomial Surfaces9.2 Spline Surfaces with Triangular Patches9.3 Spline Surfaces with Rectangular Patches9.4 Subdivision Surfaces10 Embedding an Affine Space in a Vector Space 36910.1 The "Hat Construction", or Homogenizing10.2 Affine Frames of E and Bases of E10.3 Extending Affine Maps to Linear Maps10.4 From Multiaffine Maps to Multilinear Maps10.5 Differentiating Affine Polynomial Functions Using Their Homogenized Polar Forms, Osculating Flats11 Tensor Products and Symmetric Tensor Products 39511.1 Tensor Products11.2 Symmetric Tensor Products11.3 Affine Symmetric Tensor Products11.4 Properties of Symmetric Tensor Products11.5 Polar Forms Revisited12 Appendix 1: Linear Algebra12.1 Vector Spaces12.2 Linear Maps12.3 Quotient Spaces12.4 Direct Sums12.5 Hyperplanes and Linear Forms13 Appendix 2: Complements of Affine Geometry 44213.1 Affine and Multiaffine Maps13.2 Homogenizing Multiaffine Maps13.3 Intersection and Direct Sums of Affine Spaces13.4 Osculating Flats Revisited14 Appendix 3: Topology14.1 Metric Spaces and Normed Vector Spaces14.2 Continuous Functions, Limits14.3 Normed Affine Spaces 46515 Appendix 4: Differential Calculus15.1 Directional Derivatives, Total Derivatives15.2 Jacobian Matrices

Curves and Surfaces in Geometric Modeling,

Editors: By Jean Gallier

Description

Key Features

About the author

Related Titles