Lecture: Advanced Topics in Computer Graphics I
Course
- Lecturer(s):
- Start: Thu., 12th of April 2012
- Dates: Tue. and Thu. 12:30 - 14, LBH III.03
- Course number: MA-INF 2209
- Curriculum: Master , Diploma (Graduate)
- Diploma Area: B
Exercises
- Tutor(s):
- Start: 24. April 2012
- Dates: Tue. 10:00 s.t. - 11:30, LBH I.80
Description
Digital geometric models
Digital geometric models find nowadays numerous applications ranging from industrial CAD and terrain or scientific visualization to games and movie productions.
This lecture covers all aspects of DGM from their aquisiton and representation to editing and processing. In detail it discusses the following topics:
- Methods for the generation of polygonal meshes (laser scanning, registration and integration of single mesh parts, etc.)
- Representation: point based representations, efficient mesh data structures
- Processing: reconstruction techniques, mesh compression, optimization of polygonal meshes (fairing and remeshing), mesh decimation and refinement, hierarchical representations.
Rendering
This lecture discusses advanced rendering techniques that aim at highly realistic images. Particular emphasis lies on high quality depictions of materials.
In detail the topics of this lecture are:
- Foundations of radio- and photometry
- Models for the description of optical material properties and light sources
- Transport-, volume visualization- and rendering equation
- Algorithms and techniques for the solution of the volume visualization and rendering equation
- Algorithms and techniques of image based rendering
Literature
Digital geometric models
- Mario Botsch, Leif Kobbelt, Mark Pauly, Pierre Alliez, Bruno Levy: Polygon Mesh Processing CRC Press, 2010
Rendering
- Henrik Wann Jensen: Realistic Image Synthesis Using Photon Mapping AK Peters, 2001
- Philip Dutré, Philippe Bekaert and Kavita Bala: Advanced Global Illumination AK Peters, 2003
- Peter Shirley and R. Keith Morley: Realistic Ray Tracing - Second Edition AK Peters, 2003
- Matt Phar and Greg Humphreys: Physically Based Rendering: From Theory To Implementation Morgan Kaufmann, 2004
Slides
- 0-Introduction to Geometry (PDF document, 1.7 MB)
- 1-Geometry Acquisition and Registration (PDF document, 4.4 MB)
- 2-Implicit Representations and Distance Functions (PDF document, 1.8 MB)
- 3-Volume Carving (PDF document, 1.6 MB)
- 4-Global Optimization for Shape Fitting (PDF document, 3.6 MB)
- 5-RANSAC based Shape Detection (PDF document, 1.4 MB)
- 6-Differential Geometry (PDF document, 1.8 MB)
- 7-Mesh Smoothing2012 (PDF document, 3.9 MB)
- 9-Mesh Parametrization2012 (PDF document, 4.3 MB)
- 1-Physically-Based Rendering - Raytracing (PDF document, 2.5 MB)
- 2-Color & Radiometry (PDF document, 2.6 MB)
- 3-Reflection Models (PDF document, 1.7 MB)
- 4-Advanced Reflection Models (PDF document, 1.7 MB)
- 5-Rendering Equation (PDF document, 1.3 MB)
- 6-Sampling Strategies (PDF document, 1.4 MB)
- 7-Pathtracing (PDF document, 0.9 MB)
- 8-Filtering (PDF document, 1.7 MB)
- 9-Acceleration Structures for Path Tracing (PDF document, 1.1 MB)
- 10-Photon Mapping (PDF document, 1.2 MB)
- 11-Real-time Methods (PDF document, 3.9 MB)
Assignment Sheets
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Exercise 1: PCA-ICP Assignment sheet (PDF document, 149 KB)
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Exercise 2: MC-Simplification Assignment sheet (PDF document, 130 KB)
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Exercise 3: Normals Assignment sheet (PDF document, 126 KB)
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Exercise 4: Reconstruction Assignment sheet (PDF document, 659 KB)
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Exercise 5: Smoothing and Differential Geometry Assignment sheet (PDF document, 376 KB)
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Exercise 6: Turner-Whitted-Raytracing Assignment sheet (PDF document, 148 KB)
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Exercise 7: Radiometry Assignment sheet (PDF document, 252 KB)
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Exercise 8: BRDFs Assignment sheet (PDF document, 197 KB)
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Exercise 9: Monte Carlo Pathtracing Assignment sheet (PDF document, 676 KB)
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Exercise 10: Importance Sampling Assignment sheet (PDF document, 111 KB) |
Additional Documents
- atcg1-part2-repetition (PDF document, 1.6 MB)
- Script-Szirmay-Kalos-Laszlo (PDF document, 1.8 MB)