1. Envisioning Information Lecture 14 – Scientific Visualization
Scalar 3D Data – Volume Rendering
Ken Brodlie
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2. By controlling the opacity, we can:
Volume Rendering
This is a quite different mapping technique for visualization of 3D scalar data (compared with isosurfacing)
Aims to relate volume to a partially opaque gel material - colour and opacity at a point depending on the scalar value
By controlling the opacity, we can:
EITHER show surfaces through setting opacity to 0 or 1
OR see both exterior and interior regions by grading the opacity from 0 to 1
[Note: opacity = 1 - transparency]
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3. Example - Forest Fire From Numerical Model of Forest Fire, NCAR, USA
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4. Major application area is medical imaging
Different scanning techniques include:
CT (Computed Tomography)
MRI (Magnetic Resonance Imaging)
SPECT (Single Photon Emission Computed Tomography)
Three-dimensional images constructed from multiple 2D slices
Slice
Scanners give average
value for a region - rather
than value at a point
Interslice gap
Slice
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5. Examples of Brain Scans
Magnetic
Resonance
Imaging
Computerized
Tomography
SPECT
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6. Example - Medical Imaging
Rendered
by VolPack
software
CT scan data
256x256x226
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7. Data Classification – Assigning Opacity to CT data
CT will identify fat, soft tissue and bone
Each will have known absorption levels, say ffat, fsoft_tissue, fbone
CT value
Opacity a
fsoft_tissue 1
This transfer function will highlight soft tissue
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8. Data Classificatiion – Assigning Opacity to CT Data
To show all types of tissue, we assign opacities to each type and linearly interpolate between them
CT value
Opacity a
fsoft_tissue 1
ffat
fbone
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9. Data Classification – Constructing the Gel – CT Data
opacity 
This is known
as opacity
transfer function
1.0
CT number
0.0
(f)
In practice, the boundaries between materials
are of key importance - hence a two-stage algorithm
used:
(i) Calculate  as above
(ii) Scale by gradient of function to highlight boundaries
* =  |grad f | grad f = [df/dx,df/dy,df/dz]
? So what is opacity in homogeneous areas ?
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10. Data Classification – Constructing the Gel – CT Data
Colour classification is done similarly
Known as colour transfer function
white
red
yellow
CT number
Air
Soft
Tissue
Fat
Bone
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11. Data Classification – Constructing the Gel – Temperature Data
Volume rendering is also useful for other data - eg CFD temperature
Opacity transfer function: possibly increase with temperature
Colour transfer function:
blue
(0,0,1)
red
(1,0,0)
temperature
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12. Data Classification in IRIS Explorer
The GenerateColormap tool in IRIS Explorer can be used to assign colour and transparency to data
Make sure you know how to save colourmaps from one session to another
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13. Example Storm cloud data rendered by IRIS Explorer –
Isosurface & volume
rendering
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14. There are two major techniques:
Rendering the Volume
There are two major techniques:
Ray casting
Texture mapping
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15. Ray Casting to Render the Volume
1 Assign colour and opacity to data values
Classification process assigns gel colour to the original data
2 Apply light to volume
Lighting model will give the light reflected to the viewer at any point in volume - if we know the normal
Imagine an isosurface shell through each data point - surface normal is provided by gradient vector (remember from isosurfacing!)
Thus we get colour reflected at each data point
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16. Casting the Rays and Taking Samples
3. For each pixel in image
a) cast ray from eye through pixel into volume, taking samples at regular unit intervals
b) measure colour reflected at each sample in direction of ray
c) composite colour from all samples along ray, taking into account the opacity of gel it passes through - en route to the eye
data volume
ray
eye
point
exit point
image
plane
sample points
one unit apart
(colour and
opacity by
interpolation)
entry
point
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17. Compositing the Samples Along the Ray – First Sample
opaque
background,
emitting I0 I*
eye
point
Intensity - I1
Opacity - 
Imagine block of gel, one unit wide around sample point
I* = I0 (1 - ) + I1
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18. Compositing the Samples along the Ray – Two Samples
opaque
background
eye
point
Intensity - I2
Opacity - 2
Intensity - I1
Opacity - 
I* = I0 (1 - ) + I1 from previous slide
I** = I* (1 - 2) + I2 2
= I0 (1 - 1)(1 - 2) + I11(1 - 2) + I22
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19. Compositing the Samples along a Ray
The process continues for all samples, yielding a final intensity, or colour, for the ray - and this is assigned to the pixel
try it for a third sample, then you should be able to deduce a general formula
I = S ni=0 Iii Pnj=i+1(1 - j)
Note that if one compositing step is done for each ray in turn, then the next step, and so on, the image will be created in a sweep from back to front, showing all the data (even behind opaque parts)
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20. Front to Back Compositing
Compositing can also work front-to-back: I*
eye
point
I* = n In
* = n
- cumulative
opacity
Intensity In
Opacity n
I**
eye
point
I** = I* + (1 - *)n-1In-1
** = * + (1-*)n-1
Intensity In
Opacity n
Intensity In-1
Opacity n-1
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21. Front-to-Back Compositing – Early Termination
The advantage of front-to-back compositing is that we can stop the process if the accumulated opacity reaches no point in going further
Again, you should be able to deduce the general formula if you look at three samples
can you show that front-to-back and back-to-front compositing give the same answer?
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22. Maximum Intensity Projection
When performance rather than accuracy is the goal, we can avoid compositing altogether and approximate I by maximum intensity along ray
MIP : Maximum Intensity Projection
Often used in angiography...
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23. Texture-based Volume Rendering
Volume rendering by ray casting is time-consuming
one ray per pixel
each ray involves tracking through volume calculating samples, and then compositing
different for each viewpoint
Alternative approach - using texture maps - can exploit graphics hardware
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24. Modern graphics hardware includes facility to draw a textured polygon
Texture Mapping
Modern graphics hardware includes facility to draw a textured polygon
The texture is an image with red, green, blue and alpha components…
… this is used in computer graphics to avoid constructing complex geometric models
… and we can exploit this in volume rendering
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25. Texture-based Volume Rendering
Draw from back-to-front a set of rectangles
first rectangle drawn as an area of coloured pixels, with associated opacity, as determined by transfer function and interpolation - and merged with background in a compositing operation (supported by hardware)
successive rectangles drawn on top
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26. 3D Texture-based Volume Rendering
For a given viewing direction, we would need to select slices perpendicular to this direction
This requires interpolation to get the values on the slices
Until recently this has only been possible with expensive graphics boards
volume
image
plane
3D texture mapping
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27. Comparison of Ray Casting and Texture Approaches
Texture-based
Texture-based
Ray casting
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28. Close Up
Ogle: texture-based
Vlib: ray casting
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29. Splatting Another commonly used method is splatting
Fuzzy balls around each voxel projected on to image plane
Composited in the image plane
VolumeToGeom in IRIS Explorer
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30. References Classic paper:
M. Levoy. Efficient ray tracing of volume data. ACM Trans Graphics, Vol 9, 3, pp , 1990
Recent work:
Ray casting:
S. Grimm, S. Bruckner, A. Kanitsar, E. Groller.Memory efficient acceleration structures and techniques for CPU-based volume raycasting of large data. In Proceedings of the IEEE Symposium on Volume Visualization and Graphics 2004 (Oct. 2004), pp. 1-8.
Texture-based:
K. Engel et al, Real-time volume graphics. Tutorial 28 in SIGGRAPH2004, See <
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