algorithms.mesh

ComputeMeshWarp

Link to code

Calculates a the vertex-wise warping to get surface2 from surface1. It also reports the average distance of vertices, using the norm specified as input.

Example:

import nipype.algorithms.mesh as m
dist = m.ComputeMeshWarp()
dist.inputs.surface1 = 'surf1.vtk'
dist.inputs.surface2 = 'surf2.vtk'
res = dist.run()

Inputs:

[Mandatory]
surface1: (an existing file name)
        Reference surface (vtk format) to which compute distance.
surface2: (an existing file name)
        Test surface (vtk format) from which compute distance.

[Optional]
ignore_exception: (a boolean, nipype default value: False)
        Print an error message instead of throwing an exception in case the
        interface fails to run
metric: (u'euclidean' or u'sqeuclidean', nipype default value:
         euclidean)
        norm used to report distance
out_file: (a file name, nipype default value: distance.npy)
        numpy file keeping computed distances and weights
out_warp: (a file name, nipype default value: surfwarp.vtk)
        vtk file based on surface1 and warpings mapping it to surface2
weighting: (u'none' or u'area', nipype default value: none)
        "none": no weighting is performed, surface": edge distance is
        weighted by the corresponding surface area

Outputs:

distance: (a float)
        computed distance
out_file: (an existing file name)
        numpy file keeping computed distances and weights
out_warp: (an existing file name)
        vtk file with the vertex-wise mapping of surface1 to surface2

MeshWarpMaths

Link to code

Performs the most basic mathematical operations on the warping field defined at each vertex of the input surface. A surface with scalar or vector data can be used as operator for non-uniform operations.

Example:

import nipype.algorithms.mesh as m
mmath = m.MeshWarpMaths()
mmath.inputs.in_surf = 'surf1.vtk'
mmath.inputs.operator = 'surf2.vtk'
mmath.inputs.operation = 'mul'
res = mmath.run()

Inputs:

[Mandatory]
in_surf: (an existing file name)
        Input surface in vtk format, with associated warp field as point
        data (ie. from ComputeMeshWarp
operator: (a float or a tuple of the form: (a float, a float, a
         float) or an existing file name)
        image, float or tuple of floats to act as operator

[Optional]
float_trait: (a float or a tuple of the form: (a float, a float, a
         float))
ignore_exception: (a boolean, nipype default value: False)
        Print an error message instead of throwing an exception in case the
        interface fails to run
operation: (u'sum' or u'sub' or u'mul' or u'div', nipype default
         value: sum)
        operation to be performed
out_file: (a file name, nipype default value: warped_surf.vtk)
        vtk with surface warped
out_warp: (a file name, nipype default value: warp_maths.vtk)
        vtk file based on in_surf and warpings mapping it to out_file

Outputs:

out_file: (an existing file name)
        vtk with surface warped
out_warp: (an existing file name)
        vtk file with the vertex-wise mapping of surface1 to surface2

P2PDistance

Link to code

Calculates a point-to-point (p2p) distance between two corresponding VTK-readable meshes or contours.

A point-to-point correspondence between nodes is required

Deprecated since version 1.0-dev: Use ComputeMeshWarp instead.

Inputs:

[Mandatory]
surface1: (an existing file name)
        Reference surface (vtk format) to which compute distance.
surface2: (an existing file name)
        Test surface (vtk format) from which compute distance.

[Optional]
ignore_exception: (a boolean, nipype default value: False)
        Print an error message instead of throwing an exception in case the
        interface fails to run
metric: (u'euclidean' or u'sqeuclidean', nipype default value:
         euclidean)
        norm used to report distance
out_file: (a file name, nipype default value: distance.npy)
        numpy file keeping computed distances and weights
out_warp: (a file name, nipype default value: surfwarp.vtk)
        vtk file based on surface1 and warpings mapping it to surface2
weighting: (u'none' or u'area', nipype default value: none)
        "none": no weighting is performed, surface": edge distance is
        weighted by the corresponding surface area

Outputs:

distance: (a float)
        computed distance
out_file: (an existing file name)
        numpy file keeping computed distances and weights
out_warp: (an existing file name)
        vtk file with the vertex-wise mapping of surface1 to surface2

TVTKBaseInterface

Link to code

A base class for interfaces using VTK

Inputs:

[Mandatory]

[Optional]
ignore_exception: (a boolean, nipype default value: False)
        Print an error message instead of throwing an exception in case the
        interface fails to run

Outputs:

None

WarpPoints

Link to code

Applies a displacement field to a point set given in vtk format. Any discrete deformation field, given in physical coordinates and which volume covers the extent of the vtk point set, is a valid warp file. FSL interfaces are compatible, for instance any field computed with nipype.interfaces.fsl.utils.ConvertWarp.

Example:

from nipype.algorithms.mesh import WarpPoints
wp = WarpPoints()
wp.inputs.points = 'surf1.vtk'
wp.inputs.warp = 'warpfield.nii'
res = wp.run()

Inputs:

[Mandatory]
interp: (u'cubic' or u'nearest' or u'linear', nipype default value:
         cubic)
        interpolation
points: (an existing file name)
        file containing the point set
warp: (an existing file name)
        dense deformation field to be applied

[Optional]
ignore_exception: (a boolean, nipype default value: False)
        Print an error message instead of throwing an exception in case the
        interface fails to run
out_points: (a file name)
        the warped point set

Outputs:

out_points: (a file name)
        the warped point set