Presentation is loading. Please wait.

Presentation is loading. Please wait.

Volume Rendering CMSC 491/635. Volume data  3D Scalar Field: F(x,y,z) = ?  Implicit functions  Voxel grid  Scalar data  Density  Temperature  Wind.

Published byToby James Modified over 8 years ago

Similar presentations

Presentation on theme: "Volume Rendering CMSC 491/635. Volume data  3D Scalar Field: F(x,y,z) = ?  Implicit functions  Voxel grid  Scalar data  Density  Temperature  Wind."— Presentation transcript:

1 Volume Rendering CMSC 491/635

2 Volume data  3D Scalar Field: F(x,y,z) = ?  Implicit functions  Voxel grid  Scalar data  Density  Temperature  Wind speed  …

3 Implicit functions  Blobs [Blinn 82]  Metaballs [Nishimura 83]  Soft Objects [Wyvill 86]  Polynomial approximation for exp() Philo Vivero http://faemalia.org

4 Voxels  Sampled volume  Usually in a grid  Measured  MRI, CT scan, …  Computed  Sample geometric model  Finite element simulation  …

5 Isosurface rendering  F(x,y,z) – c = 0 (for some given c)  Isosurface normal:  F  Implicit: Point repulsion [Witkin 92]  Voxel: Marching cubes [Lorensen 87]

6 Marching cubes  Estimate intersection point on each edge  Same criteria (e.g. linear interpolation)  Polygons will match  Use template for polygons  2 8 possibilities, 15 “unique”  Store templates in table

7 Marching tetrahedra  Decompose volume into tetrahedra  Avoids ambiguous “opposite corner” cases  2 4 = 16 cases, 3 unique  0 or 4 points inside (0 triangles)  1 or 3 points inside (1 triangle)  2 points inside (2 triangles)

8 Direct volume rendering  Model as translucent material  Color and extinction,  Attenuation along ray   Attenuated color at   Accumulate attenuated colors along ray 

9 Simplify volume integral  Numeric integration, step size d   Color of ray segment    Back to front composite 

10 Transfer functions  Map scalar to color and/or opacity

11 Appearance  Additive / pseudo-XRay  Volume lighting:,   Directional derivative 

12 Rendering methods  Ray casting  Splatting  Texture accumulation  Shear-warp  Fourier volume rendering

13 Ray casting  Straightforward numerical integration  Uniform steps along ray  Resample volume to sample points  Before classification and/or shading  After classification and/or shading

14 Splatting [Westover 90]  Resample directly onto screen  Each voxel contributes kernel footprint  Reconstruction + pixel filter  Accumulate back-to-front

15 Shear-warp [Lacroute 94]

16 Texture accumulation  Let texturing hardware resample  Accumulate back-to-front  3D textures  Render slices parallel to image plane  Shift accesses for,  2D texture slices  Slice sets perpendicular to each axis  Choose set most parallel to image plane

17 Pre-integrated texture [Engel 01]  Improve approximation for and  Lookup(start value, end value, d)  Dependent lookup  3D texture  2D texture  linear in d  constant d

18 Pre-integrated texture  a: shading before resampling  b: shading after resampling  c: b with interpolated slices  d: pre-integrated, same slice set as b

19 Dividing cubes  Find voxels that cross isosurface  Subdivide to pixel-sized sub-voxels  Find sub-voxels that cross isosurface  Plot as shaded points / kernel footprints

Download ppt "Volume Rendering CMSC 491/635. Volume data  3D Scalar Field: F(x,y,z) = ?  Implicit functions  Voxel grid  Scalar data  Density  Temperature  Wind."

Similar presentations

7.1 Vis_04 Data Visualization Lecture 7 3D Scalar Visualization Part 2 : Volume Rendering- Introduction.

7.1 Vis_04 Data Visualization Lecture 7 3D Scalar Visualization Part 2 : Volume Rendering- Introduction.
Reconstruction from Voxels (GATE-540)

Reconstruction from Voxels (GATE-540)
VIS Group, University of Stuttgart Tutorial T4: Programmable Graphics Hardware for Interactive Visualization Pre-Integrated Splatting (Stefan Roettger)

VIS Group, University of Stuttgart Tutorial T4: Programmable Graphics Hardware for Interactive Visualization Pre-Integrated Splatting (Stefan Roettger)
Direct Volume Rendering. What is volume rendering? Accumulate information along 1 dimension line through volume.

Direct Volume Rendering. What is volume rendering? Accumulate information along 1 dimension line through volume.
Other DVR Algorithms and A Comparison Jian Huang, CS 594, Spring 2002.

Other DVR Algorithms and A Comparison Jian Huang, CS 594, Spring 2002.
CLASS 9 ADVANCE RENDERING RAY TRACING RADIOSITY LIGHT FIELD CS770/870.

CLASS 9 ADVANCE RENDERING RAY TRACING RADIOSITY LIGHT FIELD CS770/870.
Fast High Accuracy Volume Rendering Thesis Defense May 2004 Kenneth Moreland Ph.D. Candidate Sandia is a multiprogram laboratory operated by Sandia Corporation,

Fast High Accuracy Volume Rendering Thesis Defense May 2004 Kenneth Moreland Ph.D. Candidate Sandia is a multiprogram laboratory operated by Sandia Corporation,
Volume Rendering Volume Modeling Volume Rendering Volume Modeling Volume Rendering 20 Apr. 2000.

Volume Rendering Volume Modeling Volume Rendering Volume Modeling Volume Rendering 20 Apr
Direct Volume Rendering (DVR): Ray-casting

Direct Volume Rendering (DVR): Ray-casting
CDS 301 Fall, 2009 Scalar Visualization Chap. 5 September 24, 2009 Jie Zhang Copyright ©

CDS 301 Fall, 2009 Scalar Visualization Chap. 5 September 24, 2009 Jie Zhang Copyright ©
Splatting Jian Huang, CS 594, Spring 2002 This set of slides reference slides made by Ohio State University alumuni over the past several years.

Splatting Jian Huang, CS 594, Spring 2002 This set of slides reference slides made by Ohio State University alumuni over the past several years.
University of British Columbia CPSC 314 Computer Graphics Jan-Apr 2005 Tamara Munzner Virtual Trackball, Scientific.

University of British Columbia CPSC 314 Computer Graphics Jan-Apr 2005 Tamara Munzner Virtual Trackball, Scientific.
University of British Columbia CPSC 314 Computer Graphics Jan-Apr 2005 Tamara Munzner Information Visualization.

University of British Columbia CPSC 314 Computer Graphics Jan-Apr 2005 Tamara Munzner Information Visualization.
Surface Reconstruction from 3D Volume Data. Problem Definition Construct polyhedral surfaces from regularly-sampled 3D digital volumes.

Surface Reconstruction from 3D Volume Data. Problem Definition Construct polyhedral surfaces from regularly-sampled 3D digital volumes.
Splatting Josh Anon Advanced Graphics 1/29/02. Types of Rendering Algorithms Backward mapping Image plane mapped into data Ray casting Forward mapping.

Splatting Josh Anon Advanced Graphics 1/29/02. Types of Rendering Algorithms Backward mapping Image plane mapped into data Ray casting Forward mapping.
Introduction to Volume Rendering Presented by Zvi Devir.

Introduction to Volume Rendering Presented by Zvi Devir.
Direct Volume Rendering Joe Michael Kniss Scientific Computing and Imaging Institute University of Utah.

Direct Volume Rendering Joe Michael Kniss Scientific Computing and Imaging Institute University of Utah.
Introduction to Volume Visualization Mengxia Zhu Fall 2007.

Introduction to Volume Visualization Mengxia Zhu Fall 2007.
Sorting and cell compositing for irregular meshes Nelson Max, Peter Williams, Richard Cook, Claudio Silva.

Sorting and cell compositing for irregular meshes Nelson Max, Peter Williams, Richard Cook, Claudio Silva.
Volume Visualization Acknowledgements: Torsten Möller (SFU)

Volume Visualization Acknowledgements: Torsten Möller (SFU)

Similar presentations

Ads by Google