SoROI Class Reference
[Nodes]

Large Data Management Region of Interest (subvolume) node. More...

#include <LDM/nodes/SoROI.h>

Inheritance diagram for SoROI:
SoNode SoFieldContainer SoBase SoRefCounter SoTypedObject SoROIManip

List of all members.

Public Types

enum  Flags {
  ENABLE_X0 = 0x1,
  ENABLE_Y0 = 0x2,
  ENABLE_Z0 = 0x4,
  INVERT_0 = 0x8,
  ENABLE_X1 = 0x10,
  ENABLE_Y1 = 0x20,
  ENABLE_Z1 = 0x40,
  INVERT_1 = 0x80,
  ENABLE_X2 = 0x100,
  ENABLE_Y2 = 0x200,
  ENABLE_Z2 = 0x400,
  INVERT_2 = 0x800,
  OR_SELECT = 0x1000,
  INVERT_OUTPUT = 0x2000,
  SUB_VOLUME = ENABLE_X0 | ENABLE_Y0 | ENABLE_Z0,
  EXCLUSION_BOX = SUB_VOLUME | INVERT_OUTPUT,
  CROSS = ENABLE_X0 | ENABLE_Y0 | ENABLE_Y1 | ENABLE_Z1 | ENABLE_X2 | ENABLE_Z2 | OR_SELECT,
  CROSS_INVERT = CROSS | INVERT_OUTPUT,
  FENCE = ENABLE_X0 | ENABLE_Y1 | ENABLE_Z2 | OR_SELECT,
  FENCE_INVERT = FENCE | INVERT_OUTPUT
}

Public Member Functions

virtual SoType getTypeId () const
 SoROI ()

Static Public Member Functions

static SoType getClassTypeId ()

Public Attributes

SoSFInt32 dataSetId
SoSFBox3i32 box
SoSFBitMask flags
SoSFBox3i32 subVolume
SoSFBool relative

Detailed Description

Large Data Management Region of Interest (subvolume) node.

The ROI ("region of interest") node allows you to specify a sub-region of the volume that will be rendered. Voxels within the ROI are rendered; voxels outside the ROI are not rendered. This provides a simple and very efficient form of volume clipping (much more efficient than using SoClipPlane nodes).

The SoVolumeData node on which the ROI will be applied can be specified with dataSetId. When this field is set to 0, the last SoVolumeData node on state is used.

In addition, for large volumes that cannot be fully loading into CPU and/or GPU memory, SoROI can improve both data loading performance and image quality. VolumeViz will always try to load the highest resolution data possible for the voxels inside the region defined by the ROI. VolumeViz is not required to load data in tiles that are completely outside the ROI. VolumeViz may load tiles outside the ROI if there is sufficient memory (this is useful in cases where the user can move or resize the ROI). But in general, for large volumes, using SoROI reduces the amount of data that must be loaded and increases image quality for the voxels inside the ROI.

Note that the above discussion only applies in multi-resolution mode (the default). In fixed resolution mode (see SoLDMResourceParameters::fixedResolution), VolumeViz will try to load all the tiles in the volume at the specified resolution level regardless of the SoROI settings.

The ROI can be a simple box (default) or a complex shape defined by (up to) three box shapes (X, Y, and Z slabs) and logic flags that specify how the slabs are to be combined.

SoROI is commonly used with an opaque color map to provide a "volume probe" in seismic data applications. However it is useful with any kind of volume data to limit the data displayed and to improve loading and image quality as discussed above.

The box and subVolume fields are specified in voxel coordinates. The limits are included in the ROI. A value of 0,0,0 0,0,0 (min and max) in the subVolume field means that this field should be ignored. This is the default.

This node acts on the rendering shape nodes of VolumeViz (SoVolumeRender, SoOrthoSlice, SoObliqueSlice, SoVolumeSkin, etc.)

To define a simple ROI, set the limits of the ROI in the box field (and do not set the subVolume field). The same result is obtained by setting the box and subVolume fields to the same value, but this is not necessary. But note that the default ROI box is not automatically the full volume. You must initialize the ROI box to something, for example the volume dimensions minus one.

      // Initialize ROI box to full volume
      SoVolumeData* volData = new SoVolumeData();
      . . .
      SoROIManip*   roiManip = new SoROIManip();
      roiManip->box.setValue( SbVec3i32(0,0,0), volData->data.getSize() - SbVec3i32(1,1,1) );
      root->addChild( roiManip );

For a complex ROI, the region defined by the SoROI box field always acts upon the region defined by the SoROI subVolume field, not the entire volume. For example, in EXCLUSION_BOX mode, the visible portion of the volume is the subVolume region minus the box region. You are allowed to set the box region larger than (or completely outside) the subVolume region, but only the intersection of the two regions is significant.

You can also use the convenient manipulator class SoROIManip to allow your users to interactively move and resize the region of interest.

The figures below show the subVolume field used to limit the visible portion of the volume (left) and the ROI used as an "exclusion box" to cut away part of the subvolume (right).

Example: box field used to limit visible portion of the volume
subvolume.jpg
Example: box field + subVolume field used as an exclusion box
roiexclusion.jpg

The Crop Box and Cropping Process.

The crop box is defined by three sets of parallel planes that define three slabs:

After these three planes have been specified, cropping is done in four stages.

Stage 1 determines which voxels to include relative to one or more of the slabs. Classification can be enabled or disabled relative to the X slab, Y slab, or Z slab. This classification is performed three separate times, resulting in three terms: Term 0, Term 1, and Term 2. Each term has its own logic flags that enable the three slabs, independent of the other terms. The flags are as follows:

Stage 2 determines whether to invert the values obtained in Stage 1 so that the voxels outside a slab are selected. This determination is made for each of the terms (Term 0, Term 1, Term 2). As in Stage 1, each term has its own inversion flag and is independent of the other terms.

Stage 3 creates either the union or the intersection of Term 0, Term 1, and Term 2. This is specified using a logic flag.

Stage 4 determines whether to invert the result of Stage 3 and provides the final ROI. Again, the inversion (if any) is specified using a logic flag.

Example of Cropping Process

(Figures courtesy Real Time Visualization)

The following example will show you how the cropping process works.

Start with a volume that is 100x200x100 (x, y, z). The final cropped shape will be the union of a 20x200x20 bar and a 100x25x100 box.

Here is the initial volume:

ROI_a.jpg

Here is the bar:

ROI_b.jpg

The bar can be formed in Term 0 of Stage 1 by using the intersection of the X and Z slabs, each with min and max values set to 40 and 60, respectively.

Here is the box:

ROI_c.jpg

The box can be formed in Term 1 of Stage 1 by using just the Y slab, with min and max values set to 125 and 150.

Term 2 of Stage 1 can be set to be identical to Term 0 or Term 1, or it can be set to include no samples by setting no enable flags (no slabs selected, so entire volume is selected) and setting the invert flag of Stage 2 so that the entire volume is deselected. To get the union of these terms in Stage 3, OR_SELECT is set. That results in the desired cropping, so Stage 4, in which the results are inverted, is not used.

Here is the code to set the box dimensions and the logic flags:

      SoROI* myROI = new SoROI();
      int xmin =  40; int xmax =  60;
      int ymin = 125; int ymax = 150;
      int zmin =  40; int zmax =  60;
      myROI->box.setValue( xmin, ymin, zmin, xmax, ymax, zmax );
      myROI->flags = SoROI::ENABLE_X0 | SoROI::ENABLE_Z0 | SoROI::ENABLE_Y1 | SoROI::INVERT_2 | SoROI::OR_SELECT;

Here is the resulting complex crop box:

ROI_d.jpg

Additional Examples

ROI_ex1.jpg
Example 1: flags = SUB_VOLUME

Alternate setting:flags = ENABLE_X0 | ENABLE_Y1 | ENABLE_Z2

ROI_ex2.jpg
Example 2: flags = FENCE

Alternate setting:flags = ENABLE_X0 | ENABLE_Y1 | ENABLE_Z2 | OR_SELECT

ROI_ex3.jpg
Example 3: flags = FENCE

Note that example 2 and 3 have the same flags set; but in example 2, xmin, ymin, and zmin values are set to zero. Setting its xmax, ymax, and zmax values to the maximum value produces a similar crop.

ROI_ex4.jpg
Example 4: flags = FENCE_INVERT

Alternate setting:flags = ENABLE_X0 | ENABLE_Y1 | ENABLE_Z2 | OR_SELECT | INVERT_OUTPUT

ROI_ex5.jpg
Example 5: flags = CROSS

Alternate setting:flags = ENABLE_X0 | ENABLE_Y0 | ENABLE_Y1 | ENABLE_Z1 | ENABLE_X2 | ENABLE_Z2 | OR_SELECT

ROI_ex6.jpg
Example 6: flags = CROSS_INVERT

Alternate setting:flags = CROSS | INVERT_OUTPUT

FILE FORMAT/DEFAULT

SEE ALSO

SoVolumeRender, SoOrthoSlice, SoObliqueSlice, SoROIManip

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Open Inventor Toolkit reference manual, generated on 4 Sep 2023
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