User:Davisb/EMSegmentModule: Difference between revisions
(95 intermediate revisions by 2 users not shown) | |||
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#Anatomical Structure Hierarchy: Define a hierarchy of anatomical structures. | #Anatomical Structure Hierarchy: Define a hierarchy of anatomical structures. | ||
#Spatial Priors: Assign uniform priors or probability images for each leaf node of the hierarchy. | #Spatial Priors: Assign uniform priors or probability images for each leaf node of the hierarchy. | ||
#Intensity Images: Assign target intensity images. | #Intensity Images: Assign atlas and target intensity images. | ||
#Intensity Distributions: Define an intensity distribution for each leaf node of the hierarchy. | #Intensity Distributions: Define an intensity distribution for each leaf node of the hierarchy. | ||
#Node-based Parameters: Specify node-based segmentation parameters. | #Node-based Parameters: Specify node-based segmentation parameters. | ||
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#Registration Parameters: Specify atlas-to-template registration parameters. | #Registration Parameters: Specify atlas-to-template registration parameters. | ||
#Segmentation: Apply EM algorithm to segment target image pair. | #Segmentation: Apply EM algorithm to segment target image pair. | ||
===How will the template be used?=== | ===How will the template be used?=== | ||
Line 92: | Line 91: | ||
*Specify atlas intensity input volumes | *Specify atlas intensity input volumes | ||
*Specify target input volumes | *Specify target input volumes | ||
=== Step 4: Intensity Distributions=== | === Step 4: Intensity Distributions=== | ||
Line 99: | Line 97: | ||
*parameters may be entered and edited manually | *parameters may be entered and edited manually | ||
*parameters can be learned by clicking on a representative sample of voxels in the target intensity volumes (~8 clicks) | *parameters can be learned by clicking on a representative sample of voxels in the target intensity volumes (~8 clicks) | ||
**the target images must be aligned together for this method to make sense | |||
**the user may erase a particular sample or all samples | **the user may erase a particular sample or all samples | ||
*A display will be available to visualize the intensity distributions | *A display will be available to visualize the intensity distributions | ||
Line 195: | Line 194: | ||
*joint registration & segmentation | *joint registration & segmentation | ||
Choose interpolation type from pull down list | Choose interpolation type from pull down list: | ||
*Linear | |||
*Cubic | |||
*Nearest-neighbor | |||
Alignment of input channels on/off | Alignment of input channels on/off <u>(shouldn't this should occur before intensity sampling?---bcd)</u> | ||
=== Step 8: Segmentation === | === Step 8: Segmentation === | ||
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associate image volumes with volume display parameters in Slicer3. | associate image volumes with volume display parameters in Slicer3. | ||
The following graph shows dependency information for all of the | The following graph shows dependency information for all of the nodeem | ||
types proposed for this file format. An arrow pointing from node A to | types proposed for this file format. An arrow pointing from node A to | ||
node B indicates that (1) the XML tag for each node of type A contains | node B indicates that (1) the XML tag for each node of type A contains | ||
a reference to the ID of a node of type B, and (2) the MRML node class | a reference to the ID of a node of type B, and (2) the MRML node class | ||
representing an A node contains a pointer to a MRML B node class. | representing an A node contains a pointer to a MRML B node class. Note that parent nodes in the anatomical structure hierarchy are a special case: they do not contain references to their child nodes in the XML tags. However, they do contain pointers to their child nodes in their MRML classes. | ||
Also, the prefix '''EMS''' in the graph will be expanded to '''EMSegment'''. | |||
====Template Builder (A)==== | |||
<graphviz> | |||
digraph g { | |||
graph [ | |||
rankdir = "LR" | |||
]; | |||
node [ | |||
fontsize = "10" | |||
shape = "record" | |||
]; | |||
edge [ | |||
color=red | |||
]; | |||
#nodes | |||
"TemplateBuilder" [label = "<f0>TemplateBuilder"] | |||
"Results" [label = "<f0>Results"] | |||
"Template" [label = "<f0>Template"] | |||
"Tree" [label = "<f0>Tree"] | |||
"GlobalParameters" [label = "<f0>GlobalParameters"] | |||
"Atlas" [label = "<f0>Atlas"] | |||
"Target" [label = "<f0>Target"] | |||
"Volume" [label = "<f0>Volume"] | |||
#edges | |||
"TemplateBuilder":f0 -> "Template":f0 | |||
"TemplateBuilder":f0 -> "Results":f0 | |||
"Template":f0 -> "Tree":f0 | |||
"Template":f0 -> "GlobalParameters":f0 | |||
"Tree":f0 -> "GlobalParameters":f0 | |||
"GlobalParameters":f0 -> "Atlas":f0 | |||
"GlobalParameters":f0 -> "Target":f0 | |||
"Atlas":f0 -> "Volume":f0 | |||
"Target":f0 -> "Volume":f0 | |||
} | |||
</graphviz> | |||
====Template Applyer==== | |||
<graphviz> | <graphviz> | ||
digraph g { | digraph g { | ||
graph [ | graph [ | ||
#rankdir = "LR" | rankdir = "LR" | ||
]; | |||
node [ | |||
fontsize = "10" | |||
shape = "record" | |||
]; | |||
edge [ | |||
color=red | |||
]; | |||
#nodes | |||
"TemplateApplyer" [label = "<f0>TemplateApplyer"] | |||
"Results" [label = "<f0>Results"] | |||
"Template" [label = "<f0>Template"] | |||
"TargetInput" [label = "<f0>TargetInput"] | |||
"AtlasInput" [label = "<f0>AtlasInput"] | |||
#edges | |||
"TemplateApplyer":f0 -> "Template":f0 | |||
"TemplateApplyer":f0 -> "Results":f0 | |||
"TemplateApplyer":f0 -> "AtlasInput":f0 | |||
"TemplateApplyer":f0 -> "TargetInput":f0 | |||
"AtlasInput":f0 -> "Volume":f0 | |||
"TargetInput":f0 -> "Volume":f0 | |||
} | |||
</graphviz> | |||
====Template Applyer Expanded==== | |||
<graphviz> | |||
digraph g { | |||
graph [ | |||
rankdir = "LR" | |||
]; | |||
node [ | |||
fontsize = "10" | |||
shape = "record" | |||
]; | |||
edge [ | |||
color=red | |||
]; | |||
#nodes | |||
"TemplateApplyer" [label = "<f0>TemplateApplyer"] | |||
"Results" [label = "<f0>Results"] | |||
"Template" [label = "<f0>Template"] | |||
"Tree" [label = "<f0>Tree"] | |||
"GlobalParameters" [label = "<f0>GlobalParameters"] | |||
"Atlas" [label = "<f0>Atlas"] | |||
"Target" [label = "<f0>Target"] | |||
"Volume" [label = "<f0>Volume"] | |||
"TargetInput" [label = "<f0>TargetInput"] | |||
"AtlasInput" [label = "<f0>AtlasInput"] | |||
#edges | |||
"TemplateApplyer":f0 -> "Template":f0 | |||
"TemplateApplyer":f0 -> "Results":f0 | |||
"TemplateApplyer":f0 -> "AtlasInput":f0 | |||
"TemplateApplyer":f0 -> "TargetInput":f0 | |||
"Template":f0 -> "Tree":f0 | |||
"Template":f0 -> "GlobalParameters":f0 | |||
"Tree":f0 -> "GlobalParameters":f0 | |||
"GlobalParameters":f0 -> "Atlas":f0 | |||
"GlobalParameters":f0 -> "Target":f0 | |||
"AtlasInput":f0 -> "Volume":f0 | |||
"TargetInput":f0 -> "Volume":f0 | |||
"Atlas":f0 -> "Volume":f0 | |||
"Target":f0 -> "Volume":f0 | |||
} | |||
</graphviz> | |||
====Template Builder (B)==== | |||
<graphviz> | |||
digraph g { | |||
graph [ | |||
rankdir = "LR" | |||
]; | |||
node [ | |||
fontsize = "10" | |||
shape = "record" | |||
]; | |||
edge [ | |||
color=red | |||
]; | |||
#nodes | |||
"TemplateBuilder" [label = "<f0>TemplateBuilder"] | |||
"TemplateApplyer" [label = "<f0>TemplateApplyer"] | |||
"Results" [label = "<f0>Results"] | |||
"Template" [label = "<f0>Template"] | |||
"TargetInput" [label = "<f0>TargetInput"] | |||
"AtlasInput" [label = "<f0>AtlasInput"] | |||
#edges | |||
"TemplateBuilder":f0 -> "TemplateApplyer":f0 | |||
"TemplateBuilder":f0 -> "Template":f0 | |||
"Template":f0 -> "AtlasInput":f0 | |||
"Template":f0 -> "TargetInput":f0 | |||
"TemplateApplyer":f0 -> "Template":f0 | |||
"TemplateApplyer":f0 -> "Results":f0 | |||
"TemplateApplyer":f0 -> "AtlasInput":f0 | |||
"TemplateApplyer":f0 -> "TargetInput":f0 | |||
"AtlasInput":f0 -> "Volume":f0 | |||
"TargetInput":f0 -> "Volume":f0 | |||
} | |||
</graphviz> | |||
====g5==== | |||
<graphviz> | |||
digraph g { | |||
graph [ | |||
rankdir = "LR" | |||
]; | ]; | ||
node [ | node [ | ||
Line 256: | Line 409: | ||
# nodes | # nodes | ||
# | # | ||
# volume related | |||
"emsResults" [label = "<f0>EMS"] | |||
"emsInput" [label = "<f0>EMSInput"] | |||
"volume" [label = "<f0>Volume"] | "volume" [label = "<f0>Volume"] | ||
"volumeStorage" [label = "<f0>VolumeArchetypeStorage"] | "volumeStorage" [label = "<f0>VolumeArchetypeStorage"] | ||
"volumeDisplay" [label = "<f0>VolumeDisplay"] | "volumeDisplay" [label = "<f0>VolumeDisplay"] | ||
"emsAtlas" [label = "<f0>EMSAtlas"] | |||
"template" [label = "<f0> | # EMS: global | ||
"template" [label = "<f0>EMSTemplate"] | |||
"globalDisplayParameters" [label = "<f0>EMSDisplay"] | |||
"globalAlgorithmParameters" [label = "<f0>EMSParameters"] | |||
" | # EMS: tree structure | ||
" | "hierarchyNode" [label = "<f0>EMSTree"] | ||
#"hierarchyNode:root" [label = "<f0>EMSTree| <f1>Root"] | |||
#"hierarchyNode:leaf1" [label = "<f0>EMSTree| <f1>Background"] | |||
#"hierarchyNode:sc1" [label = "<f0>EMSTree| <f1>ICC"] | |||
#"hierarchyNode:leaf2" [label = "<f0>EMSTree| <f1>White Matter"] | |||
#"hierarchyNode:leaf4" [label = "<f0>EMSTree| <f1>CSF"] | |||
" | # EMS: basic node-based parameters | ||
"genericParams" [label = "<f0>EMSTreeParametersNode"] | |||
"superclassParams" [label = "<f0>EMSTreeParametersParent"] | |||
"leafclassParams" [label = "<f0>EMSTreeParametersLeaf"] | |||
"nodeDisplayParams" [label = "<f0>EMSTreeDisplayNode"] | |||
# EMS: other node-based parameters | |||
" | "nodeRegistrationParams" [label = "<f0>EMSTreeParametersNodeRegistration"] | ||
" | "parentRegistrationParams" [label = "<f0>EMSTreeParametersParentRegistration"] | ||
" | "leafRegistrationParams" [label = "<f0>EMSTreeParametersLeafRegistration"] | ||
" | "nodePCAParams" [label = "<f0>EMSTreeParametersNodePCA"] | ||
" | "parentPCAParams" [label = "<f0>EMSTreeParametersParentPCA"] | ||
" | "leafPCAParams" [label = "<f0>EMSTreeParametersLeafPCA"] | ||
"matrix" [label = "<f0> | "nodeInhomogeneityParams" [label = "<f0>EMSTreeParametersNodeInhomogeneity"] | ||
"parentInhomogeneityParams" [label = "<f0>EMSTreeParametersParentInhomogeneity"] | |||
"leafInhomogeneityParams" [label = "<f0>EMSTreeParametersLeafInhomogeneity"] | |||
# EMS: misc | |||
"matrix" [label = "<f0>EMSCIM"] | |||
# | # | ||
# connections | # connections | ||
# | # | ||
"emsResults":f0 -> "emsInput":f0 | |||
"emsResults":f0 -> "template":f0 | |||
"emsResults":f0 -> "volume":f0 | |||
"emsInput":f0 -> "volume":f0 | |||
"template":f0 -> "globalDisplayParameters":f0 | "template":f0 -> "globalDisplayParameters":f0 | ||
"template":f0 -> "globalAlgorithmParameters":f0 | "template":f0 -> "hierarchyNode":f0 | ||
"template":f0 -> "emsAtlas":f0 | |||
"globalDisplayParameters":f0 -> "globalAlgorithmParameters":f0 | |||
" | "emsAtlas":f0 -> "volume":f0 | ||
"volume":f0 -> "volumeStorage":f0 | "volume":f0 -> "volumeStorage":f0 | ||
"volume":f0 -> "volumeDisplay":f0 | "volume":f0 -> "volumeDisplay":f0 | ||
"hierarchyNode | "hierarchyNode":f0 -> "genericParams":f0 | ||
"hierarchyNode | "hierarchyNode":f0 -> "hierarchyNode":f0 | ||
"hierarchyNode | "hierarchyNode":f0 -> "nodeDisplayParams":f0 | ||
"hierarchyNode | #"hierarchyNode":f0 -> "superclassParams":f0 | ||
"hierarchyNode | #"hierarchyNode":f0 -> "leafclassParams":f0 | ||
" | "genericParams":f0 -> "superclassParams":f0 | ||
" | "genericParams":f0 -> "leafclassParams":f0 | ||
"genericParams":f0 -> "nodePCAParams":f0 | |||
"genericParams":f0 -> "nodeRegistrationParams":f0 | |||
"genericParams":f0 -> "nodeInhomogeneityParams":f0 | |||
"genericParams":f0 -> "globalAlgorithmParameters":f0 | |||
"superclassParams":f0 -> "parentRegistrationParams":f0 | |||
"superclassParams":f0 -> "parentPCAParams":f0 | |||
"superclassParams":f0 -> "parentInhomogeneityParams":f0 | |||
"superclassParams":f0 -> "matrix":f0 | "superclassParams":f0 -> "matrix":f0 | ||
"superclassParams":f0 -> "volume":f0 | "superclassParams":f0 -> "volume":f0 | ||
"leafclassParams":f0 -> "volume":f0 | "leafclassParams":f0 -> "volume":f0 | ||
"leafclassParams":f0 -> "leafPCAParams":f0 | |||
"leafclassParams":f0 -> "leafRegistrationParams":f0 | |||
"leafclassParams":f0 -> "leafInhomogeneityParams":f0 | |||
"leafPCAParams":f0 -> "volume":f0 | |||
"parentInhomogeneityParams":f0 -> "volume":f0 | |||
} | } | ||
</graphviz> | </graphviz> | ||
===Example Template File=== | ===Example Template File=== | ||
Line 333: | Line 519: | ||
<VolumeDisplay id name> | <VolumeDisplay id name> | ||
<Volume id name storageNodeRef displayNodeRef> | <Volume id name storageNodeRef displayNodeRef> | ||
[...] | [more Volume nodes...] | ||
# | # | ||
# | # Main EMSegment node | ||
# | # | ||
< | <EMSegment | ||
id name | |||
globalDisplayNodeRef | |||
globalParametersNodeRef | |||
treeNodeRef> | |||
# | # | ||
# | # Global display parameters | ||
# | # | ||
< | <EMSegmentGlobalDisplay | ||
id name | |||
[graph display parameters...] | |||
[toggle display of advanced parameters...]> | |||
# | # | ||
# | # Global algorithm parameters | ||
# | # | ||
< | <EMSegmentGlobalParameters | ||
id name | |||
[list of atlas input volume references...] | |||
[global algorithm parameters...]> | |||
# | # | ||
# | # Hierarchy of anatomical structures | ||
# | # | ||
< | <EMSegmentTree | ||
id name | |||
[...] | parentNodeRef | ||
parametersNodeRef | |||
parametersLeafNodeRef | |||
parametersParentNodeRef | |||
displayNodeRef> | |||
[more Tree nodes...] | |||
pcaParametersLeafNodeRef | |||
inhomogeneityParametersParentNodeRef | |||
# | # | ||
# node-specific parameters | # node-specific parameters | ||
# | # | ||
< | <EMSegmentTreeParameters | ||
[...] | id name | ||
parametersRegistrationNodeRef | |||
[generic node-based algorithm parameters...]> | |||
[more TreeParameters nodes...] | |||
<EMSegmentTreeParametersParent | |||
id name | |||
parametersParentRegistrationNodeRef | |||
parametersParentPCANodeRef | |||
parametersParaentInhomogeneityNodeRef | |||
[class interactions matrix node refs...] | |||
[volume refs (not typically used)...] | |||
[parent-node specific algorithm parameters...]> | |||
[more TreeParametersParent nodes...] | |||
<EMSegmentTreeParametersLeaf | |||
id name | |||
parametersLeafPCANodeRef | |||
localPriorNodeRef | |||
[leaf-node specific algorithm parameters...]> | |||
[more TreeParametersLeaf nodes...] | |||
<EMSegmentTreeDisplay | |||
id name | |||
[node-specific display parametters...]> | |||
[more TreeDisplay nodes...] | |||
<EMSegmentCIM | |||
id name | |||
matrix> | |||
[more CIM nodes...] | |||
<EMSegmentTreeParametersNodeRegistration | |||
id name | |||
[generic node-based registration parmeters...]> | |||
[more TreeParametersNodeRegistration nodes...] | |||
< | <EMSegmentTreeParametersParentRegistration | ||
[...] | id name | ||
[parent-node specific registration parmeters...]> | |||
[more TreeParametersParentRegistration nodes...] | |||
< | <EMSegmentTreeParametersParentPCA | ||
[...] | id name | ||
[parent-node specific PCA parmeters...]> | |||
[more TreeParametersParentPCA nodes...] | |||
<EMSegmentTreeParametersLeafPCA | |||
id name | |||
[leaf-node specific PCA parmeters...]> | |||
< | [more TreeParametersLeafPCA nodes...] | ||
[...] | |||
<EMSegmentTreeParametersParentInhomogeneity | |||
id name | |||
[parent-node specific inhomogeneity parmeters...]> | |||
[more TreeParametersParentInhomogeneity nodes...] | |||
</pre> | </pre> | ||
===Detailed Description=== | ===Detailed Description=== | ||
The following list contains all possible template parameters; not all | |||
parameters will be tunable by the user during the template building | |||
process. Currently, the variables in itatlic have low priority. | |||
====Atlas Data==== | ====Atlas Data==== | ||
Line 389: | Line 633: | ||
*Spatial prior probability images that are aligned with the atlas intensity images; specified via MRML Volume nodes. | *Spatial prior probability images that are aligned with the atlas intensity images; specified via MRML Volume nodes. | ||
====EM Segment Template==== | ====Main EM Segment Template Node==== | ||
The template | The template contains references to global algorithm and display parameters as well as the class hierarchy. | ||
<pre> | |||
<EMSegment | |||
id name | |||
globalDisplayNodeRef | |||
globalParametersNodeRef | |||
atlasNodeRef | |||
targetNodeRef | |||
treeNodeRef> | |||
</pre> | |||
*Core attributes | *Core attributes | ||
**GlobalDisplayNodeRef--char* | **GlobalDisplayNodeRef--char* | ||
**GlobalParametersNodeRef--char* | **GlobalParametersNodeRef--char* | ||
** | **AtlasNodeRef--char* | ||
** | **TargetNodeRef--char* | ||
**TreeNodeRef--char* | |||
====Global EM Algorithm Parameters==== | ====Global EM Algorithm Parameters==== | ||
Global EM algorithm parameters are stored in a single node. | Global EM algorithm parameters are stored in a single node. | ||
<pre> | |||
<EMSegmentGlobalParameters | |||
id name | |||
[list of atlas input volume references...] | |||
[global algorithm parameters...]> | |||
</pre> | |||
*MRML node attributes | *MRML node attributes | ||
**Name | **Name | ||
Line 411: | Line 669: | ||
*Core attributes | *Core attributes | ||
**Alpha--double (should this be node specific?) | **Alpha--double (should this be node specific?) | ||
**AlreadyRead--int (internal state variable that should not be included?) | **''AlreadyRead--int (internal state variable that should not be included?)'' | ||
**DisableMultiThreading--int | |||
**NumberOfInputChannels--int--MaxInputChannelDef | **NumberOfInputChannels--int--MaxInputChannelDef | ||
**NumberOfTrainingSamples--int | **NumberOfTrainingSamples--int (Kilian : Should be moved to atlas node; Brad: moved) | ||
**SegmentationBoundaryMax--int[3] | **SegmentationBoundaryMax--int[3] | ||
**SegmentationBoundaryMin--int[3] | **SegmentationBoundaryMin--int[3] | ||
**WorkingDirectory--char*--PrintDir | **WorkingDirectory--char*--PrintDir | ||
*Additional core attributes (added by Brad and | *Additional core attributes (added by Brad and edited by Kilian) | ||
**List of Input channels | **List of Input channels | ||
**AlignInput - int ( | **AlignInput - int (nonzero=>target input channels will be aligned to each other prior to segmentation???) | ||
**RegistratonType--int (none, Joint, Sequential) | **RegistratonType--int (none, Joint, Sequential) | ||
***The following inputs are only relevant if RegistratonType != none | ***The following inputs are only relevant if RegistratonType != none | ||
Line 433: | Line 689: | ||
****RegistratonNonRigid--int (AG,BSpline, ..., disabled) | ****RegistratonNonRigid--int (AG,BSpline, ..., disabled) | ||
====Global EM Display Parameters==== | ====Global EM Display Parameters [not used]==== | ||
Global EM display parameters are stored in a single node. | Global EM display parameters are stored in a single node. | ||
<pre> | |||
<EMSegmentGlobalDisplay | |||
id name | |||
[graph display parameters...] | |||
[toggle display of advanced parameters...]> | |||
</pre> | |||
*MRML node attributes | *MRML node attributes | ||
**Name | **Name | ||
Line 441: | Line 704: | ||
*Core attributes | *Core attributes | ||
** | **(Graph display parameters...) | ||
**(I expect this to grow as the GUI develops) | **(I expect this to grow as the GUI develops) | ||
Line 451: | Line 713: | ||
<pre> | <pre> | ||
< | <EMSegmentTree | ||
id name | |||
parentNodeRef | |||
parametersNodeRef | |||
parametersLeafNodeRef | |||
parametersParentNodeRef | |||
displayNodeRef> | |||
</pre> | </pre> | ||
*MRML node attributes | *MRML node attributes | ||
Line 459: | Line 726: | ||
*Core attributes | *Core attributes | ||
**DisplayNodeRef--char* (for example color in graph) | |||
**ParametersLeafNodeRef--char* (leaf-node specific algorithm parameters) | |||
**ParametersNodeRef--char* (generic node-based algorithm parameters) | |||
**ParametersParentNodeRef--char* (parent-node specific algorithm parameters) | |||
**ParentNodeRef--char*--null in case of root node | **ParentNodeRef--char*--null in case of root node | ||
====Node-based Display Parameters==== | ====Node-based Display Parameters [moved to tree node]==== | ||
<pre> | |||
<EMSegmentTreeDisplay | |||
id name | |||
[node-specific display parameters...]> | |||
</pre> | |||
*MRML node attributes | *MRML node attributes | ||
**Name | **Name | ||
Line 472: | Line 746: | ||
*Core attributes | *Core attributes | ||
**Color--char*--color associated with this anatomical structure | **Color--char*--color associated with this anatomical structure | ||
**I expect that more will be added here as the GUI develops | **(I expect that more will be added here as the GUI develops) | ||
====Generic Node-based EM Algorithm Parameters==== | ====Generic Node-based EM Algorithm Parameters==== | ||
These attributes are applicable to both super-class and | |||
leaf-class MRML nodes. | leaf-class MRML nodes. | ||
<pre> | |||
<EMSegmentTreeParameters | |||
id name | |||
parametersRegistrationNodeRef | |||
[generic node-based algorithm parameters...]> | |||
</pre> | |||
*MRML node attributes | *MRML node attributes | ||
**Name | **Name | ||
Line 485: | Line 764: | ||
*Core attributes | *Core attributes | ||
**InputChannelWeights--char* | **InputChannelWeights--char* | ||
** | **LocalPriorNodeRef--char*--LocalPriorName | ||
**LocalPriorWeight--double | **LocalPriorWeight--double | ||
**PrintWeights--int | **PrintWeights--int | ||
**ClassProbability--double (need more descriptive name) | **ClassProbability--double (need more descriptive name) | ||
**ParemetersRegistrationNodeRef--char* | |||
*Experimental attributes | *Experimental attributes | ||
**ExcludeFromIncompleteEStep--int--ExcludeFromIncompleteEStepFlag | **ExcludeFromIncompleteEStep--int--ExcludeFromIncompleteEStepFlag | ||
==== | ====Parent-node Specific EM Algorithm Parameters==== | ||
Parent-node specific algorithm parameters are stored in a MRML node. | |||
node- | |||
<pre> | |||
<EMSegmentTreeParametersParent | |||
id name | |||
parametersParentRegistrationNodeRef | |||
parametersParentPCANodeRef | |||
parametersParentInhomogeneityNodeRef | |||
[class interactions matrix node refs...] | |||
[volume refs (not typically used)...] | |||
[parent-node specific algorithm parameters...]> | |||
</pre> | |||
*MRML node attributes | *MRML node attributes | ||
Line 511: | Line 793: | ||
*Core attributes | *Core attributes | ||
** | **ParametersParentRegistrationNodeRef [not implemented]--char* | ||
**ParametersParentPCANodeRef [not implemented]--char* | |||
**NumClasses--int | **NumClasses--int | ||
**PredefinedLabelMapPrefix--char* (change to mrml node ID?) | **PredefinedLabelMapPrefix [not implemented]--char* (change to mrml node ID? yes) | ||
**PrintFrequency--int | **PrintFrequency--int | ||
**PrintLabelMap--int | **PrintLabelMap--int | ||
Line 525: | Line 807: | ||
*Aditional core attributes (added by Brad) | *Aditional core attributes (added by Brad) | ||
**CIMMatrixNorthNodeRef--char* | **CIMMatrixNorthNodeRef [not implemented]--char* | ||
**CIMMatrixSouthNodeRef--char* | **CIMMatrixSouthNodeRef [not implemented]--char* | ||
**CIMMatrixEastNodeRef--char* | **CIMMatrixEastNodeRef [not implemented]--char* | ||
**CIMMatrixWestNodeRef--char* | **CIMMatrixWestNodeRef [not implemented]--char* | ||
**CIMMatrixUpNodeRef--char* | **CIMMatrixUpNodeRef [not implemented]--char* | ||
**CIMMatrixDownNodeRef--char* | **CIMMatrixDownNodeRef [not implemented]--char* | ||
*Experimental attributes | *Experimental attributes | ||
**GenerateBackgroundProbability--int | **GenerateBackgroundProbability--int | ||
**ParameterInitSubClass--int | **ParameterInitSubClass [not implemented]--int | ||
**ParameterSaveToFile--int | **ParameterSaveToFile [not implemented]--int | ||
**ParameterSetFromFile | **ParameterSetFromFile [not implemented]--int | ||
**PredefinedLabelID [not implemented]--int (how does this differ from prefix above? - this assigns the class with a certain internal id specified by the user. In the prefix above we would assign the prefix of the volume) | |||
**PredefinedLabelID--int (how does this differ from prefix above?) | |||
**PrintEMLabelMapConvergence--int | **PrintEMLabelMapConvergence--int | ||
**PrintEMWeightsConvergence--int | **PrintEMWeightsConvergence--int | ||
**PrintMFALabelMapConvergence--int | **PrintMFALabelMapConvergence--int | ||
**PrintMFAWeightsConvergence--int | **PrintMFAWeightsConvergence--int | ||
==== | ====Leaf-node specific EM Algorithm Parameters==== | ||
Leaf-node specific algorithm parameters are stored in a MRML node. | |||
<pre> | |||
<EMSegmentTreeParametersLeaf | |||
id name | |||
parametersLeafPCANodeRef | |||
localPriorNodeRef | |||
[leaf-node specific algorithm parameters...]> | |||
</pre> | |||
*MRML node attributes | *MRML node attributes | ||
Line 559: | Line 841: | ||
*Core attributes | *Core attributes | ||
**ParametersLeafPCANodeRef [not implemented]--char* | |||
**Label--int | **Label--int | ||
**LocalPriorWeight--double | **LocalPriorWeight--double | ||
Line 564: | Line 847: | ||
**LogMean--char* | **LogMean--char* | ||
**PrintQuality--int | **PrintQuality--int | ||
**ReferenceStandardFilename--char* (change to mrml node ID?) | **ReferenceStandardFilename [not implemented]--char* (change to mrml node ID? yes again this is case specific - should be defined through through target input node) | ||
*Experimental attributes | *Experimental attributes | ||
** | **''SamplingLogMean--char* (REMOVE)'' | ||
**''SamplingLogCovaraince--char* (REMOVE)'' | |||
** | |||
====Class Interaction Matrix==== | ====Class Interaction Matrix [not implemented]==== | ||
Six class interaction matrices (CIMs) are included for each parent | Six class interaction matrices (CIMs) are included for each parent | ||
node in the template. These matrices are named North, South, East, | node in the template. These matrices are named North, South, East, | ||
Line 607: | Line 869: | ||
*Core attributes | *Core attributes | ||
**Matrix--char* | **Matrix--char* | ||
====Generic node-based registration parameters [not implemented]==== | |||
<pre> | |||
<EMSegmentTreeParametersNodeRegistration | |||
id name | |||
[generic node-based registration parmeters...]> | |||
</pre> | |||
*MRML node attributes | |||
**Name | |||
**ID | |||
*Core attributes | |||
**PrintRegistrationParameters--int | |||
**PrintRegistrationSimilarityMeasure--int | |||
**EmployClassSpecificRegistration--int--RegistrationClassSpecificRegistrationFlag | |||
**RegistrationCovariance--double[9] | |||
**''RegistrationRotation--double[3]'' | |||
**''RegistrationScale--double[3]'' | |||
**''RegistrationTranslation--double[3]'' | |||
====Parent-node specific registration parameters [not implemented]==== | |||
<pre> | |||
<EMSegmentTreeParametersParentRegistration | |||
id name | |||
[parent-node specific registration parmeters...]> | |||
</pre> | |||
*MRML node attributes | |||
**Name | |||
**ID | |||
*Core attributes | |||
**RegistrationIndependentSubclassFlag--int (need different name? ) | |||
**RegistrationType--int | |||
====Parent-node specific PCA parameters [not implemented]==== | |||
<pre> | |||
<EMSegmentTreeParametersParentPCA | |||
id name | |||
[parent-node specific PCA parmeters...]> | |||
</pre> | |||
*MRML node attributes | |||
**Name | |||
**ID | |||
*Core attributes | |||
**PCAShapeModelType--int (change to hapeModelType) | |||
**PCAPrintShapeSimilarityMeasure--int (change to PrintShapeSimilarityMeasure) | |||
====Leaf-node specific PCA parameters [not implemented]==== | |||
<pre> | |||
<EMSegmentTreeParametersLeafPCA | |||
id name | |||
[leaf-node specific PCA parmeters...]> | |||
</pre> | |||
*MRML node attributes | |||
**Name | |||
**ID | |||
*Core attributes | |||
**PCALogisticBoundary--double | |||
**PCALogisticMax--double | |||
**PCALogisticMin--double | |||
**PCALogisticSlope--double | |||
**PCAMeanName--char* (a filename? change to atlas id) | |||
**PrintPCA--int | |||
====Parent-node specific Inhomogeneity parameters [currently implemented in parent node]==== | |||
<pre> | |||
<EMSegmentTreeParametersParentInhomogeneiry | |||
id name | |||
[parent-node specific inhomegeneity parmeters...]> | |||
</pre> | |||
*MRML node attributes | |||
**Name | |||
**ID | |||
*Core attributes | |||
**PrintBias--int | |||
**StopBiasCalculation--int | |||
**SmoothingKernelSigma--double--SmSigma | |||
**SmoothingKernelWidth--int--SmWidth | |||
**InhomogeneityNodeRef--char* [not implemented] (change to mrml node ID? This is actually case specific - yes it makes sense to change it to id should be defined by atlas id !) |
Latest revision as of 14:20, 11 December 2006
Project Summary
The goal of this project is to implement a Slicer3 module which creates templates that will be used in segmentation tasks. A template is composed of atlas data and a non-trivial collection of parameters for the EM segmentation algorithm. The template, which is written as an XML file, can be used later to segment new images. The target audience for this module is someone familiar with brain atlases and tissue labels, not a computer scientist.
This module will be demonstrated at the NAMIC All-Hands meeting in January 2007.
Contacts
- MIT: Polina Golland, Kilian Pohl (pohl@csail.mit.edu)
- Kitware: Brad Davis (brad.davis@kitware.com), Will Schroeder (will.schroeder@kitware.com)
General Module Description
The purpose of the module is to build a template that can be used later to segment new images. The template is composed of atlas data and a non-trivial collection of parameters for the EM segmentation algorithm. It is the user's job to specify the parameters so that the template is effective for segmenting a particular target image pair (T1 and T2, for example, from a particular scanner). Once the parameters are specified, the target images are segmented using the EM segmentation algorithm. If the results are satisfactory, the template is saved and can be used to segment new target images. If the results are not satisfactory, the parameters can be modified and the segmentation re-run.
The template building process is divided in to a sequence of steps in order to simplify template specification for the non-expert user.
What are the steps in the template building process?
- Anatomical Structure Hierarchy: Define a hierarchy of anatomical structures.
- Spatial Priors: Assign uniform priors or probability images for each leaf node of the hierarchy.
- Intensity Images: Assign atlas and target intensity images.
- Intensity Distributions: Define an intensity distribution for each leaf node of the hierarchy.
- Node-based Parameters: Specify node-based segmentation parameters.
- Global Parameters: Specify global segmentation parameters.
- Registration Parameters: Specify atlas-to-template registration parameters.
- Segmentation: Apply EM algorithm to segment target image pair.
How will the template be used?
The user will (1) load the template, (2) load a new, unsegmented set of input images, (3) tweak parameters from the template if desired, and (4) start the segmentation process. If the input images are not aligned, they will be aligned prior to the segmentation process---this will be specified by the user.
Alternately, the template can be used by a batch process to segment a collection of images.
Will this process (applying the template) require any parameters that are not included in the template?
Yes. Parameters pertaining to the target images are not stored in the template. Specifically, the template does not store the (1) target volume IDs and (2) whether or not the target images must be aligned. All other parameters should be specified in the template.
Will the template building module contain parameters that are not included in the template?
Yes. The template will not contain information regarding the target images. Also, the template will not contain intermediate data used to compute parameters for the template (e.g., intensity samples used to compute mean and covariance).
Detailed Description of Wizard Steps
Step 1: Anatomical Structure Hierarchy
Build and edit a tree anatomical structures:
- add new structure (specify name & color)
- rename node, change associated color
- remove a node
- reorganize a node (e.g., specify a new parent for this node)
Step 2: Spatial Priors
For each leaf node specify a spatial prior by one of:
- Specify a uniform prior (double in [0,1])
- Specify a prior probability map (volume node reference)
- Number of training samples for prior probability map (int)
Step 3: Intensity Images
- Specify atlas intensity input volumes
- Specify target input volumes
Step 4: Intensity Distributions
For each leaf node specify mean and covariance of multivariate Gaussian distribution:
- parameters may be entered and edited manually
- parameters can be learned by clicking on a representative sample of voxels in the target intensity volumes (~8 clicks)
- the target images must be aligned together for this method to make sense
- the user may erase a particular sample or all samples
- A display will be available to visualize the intensity distributions
- plot of distributions for input channels separately (marginal distributions, intensity vs. probability)
- 2D image visualization of probabilities for input1xinput2 intensity combinations (input1 intensity vs. input2 intensity)
- saturation is proportional to probability
- In all plots, color is based on tissue type (color selected for leaf node in tree)
- The user can choose which two input channels are displayed
- The user can toggle the display of each tissue type on and off
- When the user mouses over the MR image, the intensity under the mouse is plotted on each graph
Step 5: Node-Based Parameters
For all nodes
- Class Probability---double
- Local Prior Weight---double
- Input Channel Weights---double for each input channel, final representation is char*
- Print flags
- Weights
For leaf nodes only
- Intensity mean and covariance: this is specified in previous step
- Print flags
- PCA
- Quality
- Requires specification of reference standard volume
For parent nodes only
- Frequency---int---used by some of the print flags
- Print flags
- Registration Parameters
- Registration Similarity Measure
- Bias---uses Frequency
- Label-map---uses Frequency
- Shape Similarity Measure
- EMLabelMapConvergence
- EMWeightsConvergence
- MFALabelMapConvergence
- MFAWeightsConvergence
- Stopping Condition Parameters
- EM Type---int
- EM Value---double
- EM Max Iterations---int
- MFA Type---int
- MFA Value---double
- MFA Max Iterations---int
- Bias Calculation---int
- Miscellaneous Parameters
- Local Prior Name---char*
- Registration Translation---double[3]
- Registration Rotation---double[3]
- Registration Scale---double[3]
- Registration Covariance---double[9]
- Registration Class Specific Registration Flag
- Exclude From Incomplete E-Step Flag
- Registration Type---int
- Generate Background Probability Flag
- PCA Shape Model Type---int
- Registration Independent Sub-class Flag
- Class Interaction Matrices
- 6 matrices: North, South, East, West, Up, Down; choose from list
- Each matrix is of size (number of subclasses) by (number of subclasses)
- Each element is a double
- The final representation for each matrix is char*
Step 6: Global Parameters
- Alpha---double
- Smoothing Kernel Width---int
- Smoothing Kernel Sigma---double
- Multi-threading Enabled---on/off
- Working Directory---char*
- SegmentationBoundaryMax--int[3]
- SegmentationBoundaryMin--int[3]
Non-template options:
- Run Remotely---on/off
- Remote Server---char*---should be something like davisb@swan.cs.unc.edu
Step 7: Registration Parameters
What type of registration should be run: a pull down list.
- Affine
- MI
- ....
- disabled
- non rigid
- Bspline
- AG
- ....
- disabled
- joint registration & segmentation
Choose interpolation type from pull down list:
- Linear
- Cubic
- Nearest-neighbor
Alignment of input channels on/off (shouldn't this should occur before intensity sampling?---bcd)
Step 8: Segmentation
- The user can save the template before or after running the algorithm
- Run Algorithm
- Progress bar
- User can interrupt execution
- At completion the user can
- visualize segmentations as overlays on the loaded image volumes
- press button to remove small islands
- press button to generate 3D modeles
Description of MRML Nodes
Overview
By writing out a template we just mean writing the MRML tree.
The template will include atlas data (i.e. specification of image files), anatomical structure hierarchy information, algorithm parameters, and display parameters (e.g., the graph color for a particular structure). The data, hierarchy, parameter, and display information will be defined in separate nodes. Dependencies and hierarchical structure will be maintained by references: for example, a leaf node will contain a reference to the ID of its parent node. This is the idiom that is used, for example, to nest transforms and associate image volumes with volume display parameters in Slicer3.
The following graph shows dependency information for all of the nodeem types proposed for this file format. An arrow pointing from node A to node B indicates that (1) the XML tag for each node of type A contains a reference to the ID of a node of type B, and (2) the MRML node class representing an A node contains a pointer to a MRML B node class. Note that parent nodes in the anatomical structure hierarchy are a special case: they do not contain references to their child nodes in the XML tags. However, they do contain pointers to their child nodes in their MRML classes. Also, the prefix EMS in the graph will be expanded to EMSegment.
Template Builder (A)
Template Applyer
Template Applyer Expanded
Template Builder (B)
g5
Example Template File
# # NB: Only the keys are included, not the values. # # # atlas data (intensity and probabiliy maps) are stored in volume nodes # <VolumeArchetypeStorage id name> <VolumeDisplay id name> <Volume id name storageNodeRef displayNodeRef> [more Volume nodes...] # # Main EMSegment node # <EMSegment id name globalDisplayNodeRef globalParametersNodeRef treeNodeRef> # # Global display parameters # <EMSegmentGlobalDisplay id name [graph display parameters...] [toggle display of advanced parameters...]> # # Global algorithm parameters # <EMSegmentGlobalParameters id name [list of atlas input volume references...] [global algorithm parameters...]> # # Hierarchy of anatomical structures # <EMSegmentTree id name parentNodeRef parametersNodeRef parametersLeafNodeRef parametersParentNodeRef displayNodeRef> [more Tree nodes...] pcaParametersLeafNodeRef inhomogeneityParametersParentNodeRef # # node-specific parameters # <EMSegmentTreeParameters id name parametersRegistrationNodeRef [generic node-based algorithm parameters...]> [more TreeParameters nodes...] <EMSegmentTreeParametersParent id name parametersParentRegistrationNodeRef parametersParentPCANodeRef parametersParaentInhomogeneityNodeRef [class interactions matrix node refs...] [volume refs (not typically used)...] [parent-node specific algorithm parameters...]> [more TreeParametersParent nodes...] <EMSegmentTreeParametersLeaf id name parametersLeafPCANodeRef localPriorNodeRef [leaf-node specific algorithm parameters...]> [more TreeParametersLeaf nodes...] <EMSegmentTreeDisplay id name [node-specific display parametters...]> [more TreeDisplay nodes...] <EMSegmentCIM id name matrix> [more CIM nodes...] <EMSegmentTreeParametersNodeRegistration id name [generic node-based registration parmeters...]> [more TreeParametersNodeRegistration nodes...] <EMSegmentTreeParametersParentRegistration id name [parent-node specific registration parmeters...]> [more TreeParametersParentRegistration nodes...] <EMSegmentTreeParametersParentPCA id name [parent-node specific PCA parmeters...]> [more TreeParametersParentPCA nodes...] <EMSegmentTreeParametersLeafPCA id name [leaf-node specific PCA parmeters...]> [more TreeParametersLeafPCA nodes...] <EMSegmentTreeParametersParentInhomogeneity id name [parent-node specific inhomogeneity parmeters...]> [more TreeParametersParentInhomogeneity nodes...]
Detailed Description
The following list contains all possible template parameters; not all parameters will be tunable by the user during the template building process. Currently, the variables in itatlic have low priority.
Atlas Data
- Atlas intensity images; specified via MRML Volume nodes.
- Spatial prior probability images that are aligned with the atlas intensity images; specified via MRML Volume nodes.
Main EM Segment Template Node
The template contains references to global algorithm and display parameters as well as the class hierarchy.
<EMSegment id name globalDisplayNodeRef globalParametersNodeRef atlasNodeRef targetNodeRef treeNodeRef>
- Core attributes
- GlobalDisplayNodeRef--char*
- GlobalParametersNodeRef--char*
- AtlasNodeRef--char*
- TargetNodeRef--char*
- TreeNodeRef--char*
Global EM Algorithm Parameters
Global EM algorithm parameters are stored in a single node.
<EMSegmentGlobalParameters id name [list of atlas input volume references...] [global algorithm parameters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- Alpha--double (should this be node specific?)
- AlreadyRead--int (internal state variable that should not be included?)
- DisableMultiThreading--int
- NumberOfInputChannels--int--MaxInputChannelDef
- NumberOfTrainingSamples--int (Kilian : Should be moved to atlas node; Brad: moved)
- SegmentationBoundaryMax--int[3]
- SegmentationBoundaryMin--int[3]
- WorkingDirectory--char*--PrintDir
- Additional core attributes (added by Brad and edited by Kilian)
- List of Input channels
- AlignInput - int (nonzero=>target input channels will be aligned to each other prior to segmentation???)
- RegistratonType--int (none, Joint, Sequential)
- The following inputs are only relevant if RegistratonType != none
- RegistratonInterpolationType--int (linear, nn, cubic )
- The following inputs are only relevant if RegistratonType = Sequential
- RegistrationInputRef--char* (which of the input channels should be used for aligning the atlas)
- RegistrationAtlasImageRef--char* (Image representing the coordinate system of the atlas)
- RegistratonAffine--int (MI,..., disabled)
- RegistratonNonRigid--int (AG,BSpline, ..., disabled)
- The following inputs are only relevant if RegistratonType != none
Global EM Display Parameters [not used]
Global EM display parameters are stored in a single node.
<EMSegmentGlobalDisplay id name [graph display parameters...] [toggle display of advanced parameters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- (Graph display parameters...)
- (I expect this to grow as the GUI develops)
Hierarchy of Anatomical Structures
The hierarchy of anatomical structures is defined by a sequence of nodes. The nodes that define the hierarchy are separate from nodes that contain algorithm or display parameters.
<EMSegmentTree id name parentNodeRef parametersNodeRef parametersLeafNodeRef parametersParentNodeRef displayNodeRef>
- MRML node attributes
- Name
- ID
- Core attributes
- DisplayNodeRef--char* (for example color in graph)
- ParametersLeafNodeRef--char* (leaf-node specific algorithm parameters)
- ParametersNodeRef--char* (generic node-based algorithm parameters)
- ParametersParentNodeRef--char* (parent-node specific algorithm parameters)
- ParentNodeRef--char*--null in case of root node
Node-based Display Parameters [moved to tree node]
<EMSegmentTreeDisplay id name [node-specific display parameters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- Color--char*--color associated with this anatomical structure
- (I expect that more will be added here as the GUI develops)
Generic Node-based EM Algorithm Parameters
These attributes are applicable to both super-class and leaf-class MRML nodes.
<EMSegmentTreeParameters id name parametersRegistrationNodeRef [generic node-based algorithm parameters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- InputChannelWeights--char*
- LocalPriorNodeRef--char*--LocalPriorName
- LocalPriorWeight--double
- PrintWeights--int
- ClassProbability--double (need more descriptive name)
- ParemetersRegistrationNodeRef--char*
- Experimental attributes
- ExcludeFromIncompleteEStep--int--ExcludeFromIncompleteEStepFlag
Parent-node Specific EM Algorithm Parameters
Parent-node specific algorithm parameters are stored in a MRML node.
<EMSegmentTreeParametersParent id name parametersParentRegistrationNodeRef parametersParentPCANodeRef parametersParentInhomogeneityNodeRef [class interactions matrix node refs...] [volume refs (not typically used)...] [parent-node specific algorithm parameters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- ParametersParentRegistrationNodeRef [not implemented]--char*
- ParametersParentPCANodeRef [not implemented]--char*
- NumClasses--int
- PredefinedLabelMapPrefix [not implemented]--char* (change to mrml node ID? yes)
- PrintFrequency--int
- PrintLabelMap--int
- StopEMMaxIteration--int--StopEMMaxIter
- StopEMType--int
- StopEMValue--double
- StopMFAMaxIteration--int--StopMFAMaxIter
- StopMFAType--int
- StopMFAValue--double
- Aditional core attributes (added by Brad)
- CIMMatrixNorthNodeRef [not implemented]--char*
- CIMMatrixSouthNodeRef [not implemented]--char*
- CIMMatrixEastNodeRef [not implemented]--char*
- CIMMatrixWestNodeRef [not implemented]--char*
- CIMMatrixUpNodeRef [not implemented]--char*
- CIMMatrixDownNodeRef [not implemented]--char*
- Experimental attributes
- GenerateBackgroundProbability--int
- ParameterInitSubClass [not implemented]--int
- ParameterSaveToFile [not implemented]--int
- ParameterSetFromFile [not implemented]--int
- PredefinedLabelID [not implemented]--int (how does this differ from prefix above? - this assigns the class with a certain internal id specified by the user. In the prefix above we would assign the prefix of the volume)
- PrintEMLabelMapConvergence--int
- PrintEMWeightsConvergence--int
- PrintMFALabelMapConvergence--int
- PrintMFAWeightsConvergence--int
Leaf-node specific EM Algorithm Parameters
Leaf-node specific algorithm parameters are stored in a MRML node.
<EMSegmentTreeParametersLeaf id name parametersLeafPCANodeRef localPriorNodeRef [leaf-node specific algorithm parameters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- ParametersLeafPCANodeRef [not implemented]--char*
- Label--int
- LocalPriorWeight--double
- LogCovariance--char*
- LogMean--char*
- PrintQuality--int
- ReferenceStandardFilename [not implemented]--char* (change to mrml node ID? yes again this is case specific - should be defined through through target input node)
- Experimental attributes
- SamplingLogMean--char* (REMOVE)
- SamplingLogCovaraince--char* (REMOVE)
Class Interaction Matrix [not implemented]
Six class interaction matrices (CIMs) are included for each parent node in the template. These matrices are named North, South, East, West, Up, and Down. These names correspond to positive and negative cardinal directions within the target image space. The element at row i and column j of the North CIM describes the probability that a voxel with class label i will be found North of a voxel with class label j.
CIMs are represented in the template by EMSegmentCIM nodes.
<EMSegmentCIM id name [matrix entries]>
- MRML node attributes
- Name
- ID
- Core attributes
- Matrix--char*
Generic node-based registration parameters [not implemented]
<EMSegmentTreeParametersNodeRegistration id name [generic node-based registration parmeters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- PrintRegistrationParameters--int
- PrintRegistrationSimilarityMeasure--int
- EmployClassSpecificRegistration--int--RegistrationClassSpecificRegistrationFlag
- RegistrationCovariance--double[9]
- RegistrationRotation--double[3]
- RegistrationScale--double[3]
- RegistrationTranslation--double[3]
Parent-node specific registration parameters [not implemented]
<EMSegmentTreeParametersParentRegistration id name [parent-node specific registration parmeters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- RegistrationIndependentSubclassFlag--int (need different name? )
- RegistrationType--int
Parent-node specific PCA parameters [not implemented]
<EMSegmentTreeParametersParentPCA id name [parent-node specific PCA parmeters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- PCAShapeModelType--int (change to hapeModelType)
- PCAPrintShapeSimilarityMeasure--int (change to PrintShapeSimilarityMeasure)
Leaf-node specific PCA parameters [not implemented]
<EMSegmentTreeParametersLeafPCA id name [leaf-node specific PCA parmeters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- PCALogisticBoundary--double
- PCALogisticMax--double
- PCALogisticMin--double
- PCALogisticSlope--double
- PCAMeanName--char* (a filename? change to atlas id)
- PrintPCA--int
Parent-node specific Inhomogeneity parameters [currently implemented in parent node]
<EMSegmentTreeParametersParentInhomogeneiry id name [parent-node specific inhomegeneity parmeters...]>
- MRML node attributes
- Name
- ID
- Core attributes
- PrintBias--int
- StopBiasCalculation--int
- SmoothingKernelSigma--double--SmSigma
- SmoothingKernelWidth--int--SmWidth
- InhomogeneityNodeRef--char* [not implemented] (change to mrml node ID? This is actually case specific - yes it makes sense to change it to id should be defined by atlas id !)