1. A Visualization System For Mineral Elasticity Richard Perkins

2. Introduction Objectives : To continue development on the interactive elasticity visualization system To interactively visualize elastic constants and wave velocities-direction data of crystals with different pressures, temperatures and compositional factors To support remote visualization Client-Server architecture approach To support an online data repository

3. Visualization Algorithm Use elastic constants as input Solve Cristoffel’s equation to obtain wave velocities-direction data Display computed velocities as continuous surfaces Provide interactive graphic user interface

4. Definitions Elasticity/Elastic When a material is elastic it deforms under stress but return to its original state when the stress is removed Elastic constants (C ij ’s) The relation between stress and strain as defined in Hooke’s Law Used to define the elasticity of a crystal as a multivariate physical quantity Wave velocity-direction data Calculated from the elastic constants and wave propagation direction using Cristoffel’s equation Produces three sets of wave velocities-direction data: a longitudinal wave parallel to the propagation direction and two shear waves perpendicular to the propagation direction Anisotropic factors Are used to compare the velocities of the different waves

5. Plots Star plots and parallel plots Used to directly represent the elastic constants An-plot Plots anisotropy factors for longitudinal and shear waves Polygon-base surface rendering Graphically represent the three waves (one longitudinal and two shear waves)

7. Polygon-based surface Rendering How waves are rendered Use an icosahedron in which each vertex on the surface represents a propagation direction Recursively subdivide triangles into 4 triangle thereby increasing the number of vertexes Use the wave velocity-direction data calculated from Cristoffel’s equation to figure out each velocity at each vertex (propagation direction) Re-position the vertices in 3D space to represent the velocity-direction distribution.___

8. 1 st Degree 80 triangles 2 nd Degree 320 triangles 3 rd Degree 1280 triangles 4 th Degree 5120 triangles

9. Velocity-direction Features Features pertaining to wave velocity-direction rendering Views 3d velocity XY/YZ/ZX plane Frame Solid/wire Shading Enables/Disabled/Scaled Axis Degree

11. Other Features Personalized line color and thickness Single and Multiple mode Temperature and pressure Zooming Clear screen Removal of data from screen Data being visualized is selected in tree Manipulation of star plot which include: Changing axes Removing axes Rotating axes … And many more

12. Conclusion Our system allows us to visualize elastic constants and wave velocities as a function of pressure, temperature and composition Our system visualizes the data through the use of star plots, parallel plots, an-plots, and polygon-based surface rendering

13. Future Prospects Make remote application access more user friendly Expand the database Extend the visualization system to polycrystalline and multiphase composites Make the visualization system more user interactive