1. CS591: Introduction Mengxia Zhu Fall 2007

2. Class objective To study visualization principles, techniques and algorithms which are used for exploring, transforming and viewing data as computer images to gain understanding and insight into the data. Introduction to basics of parallel computing and MPI for large scale scientific datasets.

3. Course materials No textbook required Lecture notes  Posted on http://www.cs.siu.edu/~mengxia/Teaching.htm Research papers  Distributed/referred in class Web sources  Referenced in lectures

4. My expectation Experience in C programming Basic Algebra and calculus Basic understanding of computer graphics and OpenGL A little deprivation of sleep…

5. Grading Policy Midterm and final exam Grading items:  Homework: 20%  Mid term and final exam: 30%  Lab projects: 40%  Paper presentation: 10% Grading Scale:  A = 85% or more  B = 75% to 84%  C = 65% to 74%  D = 50% to 64%  F = below 50% Late submission will be punished. Academic dishonesty will be treated seriously

6. Office Hours Regular Hours  M, W, F: 12:00PM — 12:50PM Special Hours  Any time by appointment Contact Info  Office: Faner 2142  Email: mzhu@cs.siu.edumzhu@cs.siu.edu  Phone: (618)453-6057

7. Computer Graphics for Visualization OpenGL Drawing geometric objects Viewing Interception and Culling Lighting and Shading Special topics

8. Scientific Visualization Isosurface rendering Volume rendering  Splatting  Raycasting Vector and tensor visualization

9. What Visualization? Process of making a computer image or graph for giving an insight on data/information  Transforming abstract, physical data/information to a form that can be seen  Interpreting in visual terms or putting into visual forms (i.e., into pictures) Cognitive process  Form a mental image of something  Internalize an understanding

10. Visualization Process Computation: -simulation/modeling Measured/Scanned Data: - CT, MRI, ultrasound Financial data: - transactions per day Data TransformMapDisplay

11. Viz vs. Graphics vs.. Imaging Imaging - Enhance, analyze, manipulate images Graphics - Make pictures! geometric data is stored in the computer for the purposes of performing calculations and rendering 2D images Visualization - Exploration, transformation, viewing data as images

12. Relation To Other Fields Visualization Vision Signal/Image Processing Illumination Engineering Optics Computational Geometry Applied Mathematics Hardware User Interfaces Psychology Cognition

13. Extends our vision  Removes limits of human vision in space, time, frequency and complexity  Creates images or pictures of things that otherwise can not be seen See an object’s internal structure (visible man) See things that are far away or slow in evolution (stars and nebulas) See microscopic world (crystal structure) See things that move very fast (molecular dynamics) Why?

14. Human Inner Organs Visible (voxel) man  Reconstruction of human body from tomographic datasets of dissected real body www.uke.uni-hamburg.de

15. Stars and Emission Nebulas Visualizing Orion Nebula: Nadeau et al., Computer Graphs Forum, 20: 27 (2001)

16. Crystal Structure MgSiO3 perovskite An orthorhombic unit cell Atomic coordination

17. Types of Visualization Scientific Visualization  Scientific data Information Visualization  abstract data has no inherent spatial structure thus it does not allow for a straightforward mapping to any geometry with arbitrary relationship Data Visualization  A more general term  data sources beyond science such as financial, marketing, or business data  Broad enough to encompass both scientific and information visualization

18. Scientific Visualization Relates to and represents something physical or geometric  Images of human brain  Air flow over a wing Data come from scientific computing and measurements

19. Scientific Computing Real materials simulation/modeling  Electronic calculations  Atomistic MD (molecular dynamics) modeling  Finite element (continuum) modeling Solving differential equations  Computational fluid dynamics  Temperature distribution  Electromagnetic field

20. Example: Air Flow over Windshield Air flow coming from a dashboard vent and striking the windshield of an automobile http://www- fp.mcs.anl.gov/ fl

21. Measurement: Medical Imaging Standard brain CT image Volume rendered brain image http://www.gemedicalsystems.com Ultrasound

22. Challenges? Scale Dimensionality Data types Presentation Interactivity

23. Data Explosion How to make sense out of the datasets when they become very large Scientific data  A million-atom simulation: 7 GB/step  Satellite or space station: TB/day  MRI dataset: 2563 = 16 MB/slice  Laser scanning: 2 million points/minute

24. Dimensionality Three dimension (trivariate data)  We are in 3D world  Volume visualization (mapping 3D data to 2D screen) Multidimension (hypervariate data)  Car attributes: Make, model, year, miles per gallon, cost, no. of cylinders, size, weight  How to display relationships between many variables

25. Data Types Structured versus unstructured data  Unstructured (irregular) data are less compact and efficient  Preprocessing of data Scalar, vector and tensor data  Density, temperature  Data from flow dynamics  Stress-strain data Non-numerical data  Ordinal: days of the week  Categorical data: names of animals

26. Presentation Problem Display without ambiguity  Colors, lighting, translucent, animation, texture mapping Too much data for too little display area (screen)  Too many cases  Too many variables Need to highlight particular cases or variables

27. Interactivity Visualization is naturally interactive  Real-time interactions, i.e, virtual environments  Show multiple different perspectives on the data