Provided by: ants_2.2.0-1ubuntu1_amd64 bug

NAME

       antsRegistration - part of ANTS registration suite

DESCRIPTION

   COMMAND:
              antsRegistration

              This  program  is a user-level registration application meant to utilize ITKv4-only
              classes. The user can specify any number of "stages" where a stage  consists  of  a
              transform;  an  image  metric; and iterations, shrink factors, and smoothing sigmas
              for each level. Note that explicitly setting the dimensionality, metric, transform,
              output, convergence, shrink-factors, and smoothing-sigmas parameters is mandatory.

   OPTIONS:
       --version

              Get Version Information.

       -d, --dimensionality 2/3

              This option forces the image to be treated as a specified-dimensional image. If not
              specified, we try to infer the dimensionality from the input image.

       -o, --output outputTransformPrefix

              [outputTransformPrefix,<outputWarpedImage>,<outputInverseWarpedImage>]

              Specify the output transform prefix (output format is .nii.gz  ).  Optionally,  one
              can  choose  to  warp  the  moving  image  to  the  fixed space and, if the inverse
              transform exists, one can also output the warped fixed image. Note  that  only  the
              images  specified  in  the first metric call are warped. Use antsApplyTransforms to
              warp other images using the resultant transform(s).

       -j, --save-state saveSateAsTransform

              Specify the output file for the current state of the registration. The  state  file
              is  written  to  an hdf5 composite file. It is specially usefull if we want to save
              the current state of a SyN registration to the disk, so we  can  load  and  restore
              that later to continue the next registration process directly started from the last
              saved  state.   The   output   file   of   this   flag   is   the   same   as   the
              write-composite-transform,  unless  the  last transform is a SyN transform. In that
              case, the inverse displacement field of the SyN transform  is  also  added  to  the
              output  composite  transform.  Again  notice  that this file cannot be treated as a
              transform, and restore-state option must be used to load the written file  by  this
              flag.

       -k, --restore-state restoreStateAsATransform

              Specify  the  initial  state  of  the  registration  which  get immediately used to
              directly initialize the registration process. The flag is mutually  exclusive  with
              other    intialization    flags.If    this    flag    is    used,   none   of   the
              initial-moving-transform and initial-fixed-transform cannot be used.

       -a, --write-composite-transform 1/(0)

              Boolean specifying whether or not the composite transform (and its inverse,  if  it
              exists)  should  be  written to an hdf5 composite file. This is false by default so
              that only the transform for each stage is written to file.  <VALUES>: 0

       -p, --print-similarity-measure-interval <unsignedIntegerValue>

              Prints out the CC similarity metric measure between the full-size input  fixed  and
              the  transformed  moving  images  at  each  iteration  a  value  of 0 (the default)
              indicates that the full scale computation should not take  placeany  value  greater
              than 0 represents the interval of full scale metric computation.  <VALUES>: 0

       --write-interval-volumes <unsignedIntegerValue>

              Writes  out  the  output  volume  at  each  iteration.  It  helps  to  present  the
              registration process as a short movie a value of 0  (the  default)  indicates  that
              this  option  should not take placeany value greater than 0 represents the interval
              between the iterations which outputs are written to the disk.  <VALUES>: 0

       -z, --collapse-output-transforms (1)/0

              Collapse  output  transforms.  Specifically,  enabling  this  option  combines  all
              adjacent  transforms  wherepossible.  All adjacent linear transforms are written to
              disk in the forman itk affine transform (called xxxGenericAffine.mat).   Similarly,
              all  adjacent displacement field transforms are combined when written to disk (e.g.
              xxxWarp.nii.gz and xxxInverseWarp.nii.gz (if available)).Also, an output  composite
              transform  including  the  collapsed  transforms  is  written  to  the disk (called
              outputCollapsed(Inverse)Composite).  <VALUES>: 1

       -i, --initialize-transforms-per-stage (1)/0

              Initialize linear transforms from the previous stage. By enabling this option,  the
              current  linear  stage  transform  is directly intialized from the previous stage's
              linear transform; this allows multiple linear stages to be  run  where  each  stage
              directly  updates  the  estimated  linear  transform from the previous stage. (e.g.
              Translation -> Rigid -> Affine).  <VALUES>: 0

       -n, --interpolation Linear
              NearestNeighbor                        MultiLabel[<sigma=imageSpacing>,<alpha=4.0>]
              Gaussian[<sigma=imageSpacing>,<alpha=1.0>]   BSpline[<order=3>]  CosineWindowedSinc
              WelchWindowedSinc              HammingWindowedSinc              LanczosWindowedSinc
              GenericLabel[<interpolator=Linear>]

              Several  interpolation  options  are  available  in  ITK.  These have all been made
              available. Currently the interpolator choice is only used  to  warp  (and  possibly
              inverse warp) the final output image(s).

       -g, --restrict-deformation PxQxR

              This option allows the user to restrict the optimization of the displacement field,
              translation, rigid or affine transform on a per-component basis.  For  example,  if
              one  wants  to  limit  the  deformation  or rotation of 3-D volume to the first two
              dimensions, this is possible by  specifying  a  weight  vector  of  '1x1x0'  for  a
              deformation  field  or  '1x1x0x1x1x0'  for a rigid transformation.  Low-dimensional
              restriction only works if there are no preceding transformations.

       -q, --initial-fixed-transform initialTransform
              [initialTransform,<useInverse>] [fixedImage,movingImage,initializationFeature]

              Specify the initial fixed transform(s) which get immediately incorporated into  the
              composite  transform.  The  order of the transforms is stack-esque in that the last
              transform specified on the command line is the first to be applied. In addition  to
              initialization  with  ITK  transforms,  the user can perform an initial translation
              alignment by specifying the fixed and moving images and selecting an initialization
              feature.  These features include using the geometric center of the images (=0), the
              image intensities (=1), or the origin of the images (=2).

       -r, --initial-moving-transform initialTransform
              [initialTransform,<useInverse>] [fixedImage,movingImage,initializationFeature]

              Specify the initial moving transform(s) which get immediately incorporated into the
              composite  transform.  The  order of the transforms is stack-esque in that the last
              transform specified on the command line is the first to be applied. In addition  to
              initialization  with  ITK  transforms,  the user can perform an initial translation
              alignment by specifying the fixed and moving images and selecting an initialization
              feature.  These features include using the geometric center of the images (=0), the
              image intensities (=1), or the origin of the images (=2).

       -m,                                                                               --metric
              CC[fixedImage,movingImage,metricWeight,radius,<samplingStrategy={None,Regular,Random}>,<samplingPercentage=[0,1]>]

              MI[fixedImage,movingImage,metricWeight,numberOfBins,<samplingStrategy={None,Regular,Random}>,<samplingPercentage=[0,1]>]
              Mattes[fixedImage,movingImage,metricWeight,numberOfBins,<samplingStrategy={None,Regular,Random}>,<samplingPercentage=[0,1]>]
              MeanSquares[fixedImage,movingImage,metricWeight,radius=NA,<samplingStrategy={None,Regular,Random}>,<samplingPercentage=[0,1]>]
              Demons[fixedImage,movingImage,metricWeight,radius=NA,<samplingStrategy={None,Regular,Random}>,<samplingPercentage=[0,1]>]
              GC[fixedImage,movingImage,metricWeight,radius=NA,<samplingStrategy={None,Regular,Random}>,<samplingPercentage=[0,1]>]
              ICP[fixedPointSet,movingPointSet,metricWeight,<samplingPercentage=[0,1]>,<boundaryPointsOnly=0>]
              PSE[fixedPointSet,movingPointSet,metricWeight,<samplingPercentage=[0,1]>,<boundaryPointsOnly=0>,<pointSetSigma=1>,<kNeighborhood=50>]
              JHCT[fixedPointSet,movingPointSet,metricWeight,<samplingPercentage=[0,1]>,<boundaryPointsOnly=0>,<pointSetSigma=1>,<kNeighborhood=50>,<alpha=1.1>,<useAnisotropicCovariances=1>]
              IGDM[fixedImage,movingImage,metricWeight,fixedMask,movingMask,<neighborhoodRadius=0x0>,<intensitySigma=0>,<distanceSigma=0>,<kNeighborhood=1>,<gradientSigma=1>]

              These  image  metrics are available--- CC: ANTS neighborhood cross correlation, MI:
              Mutual information, Demons: (Thirion), MeanSquares, and GC: Global Correlation. The
              "metricWeight" variable is used to modulate the per stage weighting of the metrics.
              The metrics can also employ a sampling strategy defined by a  sampling  percentage.
              The  sampling  strategy  defaults to 'None' (aka a dense sampling of one sample per
              voxel), otherwise it defines a point set over which to  optimize  the  metric.  The
              point  set  can  be  on  a  regular  lattice or a random lattice of points slightly
              perturbed to minimize aliasing artifacts.  samplingPercentage defines the  fraction
              of  points  to  select  from  the  domain. In addition, three point set metrics are
              available:    Euclidean     (ICP),     Point-set     expectation     (PSE),     and
              Jensen-Havrda-Charvet-Tsallis (JHCT).

       -t, --transform Rigid[gradientStep]
              Affine[gradientStep]     CompositeAffine[gradientStep]     Similarity[gradientStep]
              Translation[gradientStep]                 BSpline[gradientStep,meshSizeAtBaseLevel]
              GaussianDisplacementField[gradientStep,updateFieldVarianceInVoxelSpace,totalFieldVarianceInVoxelSpace]
              BSplineDisplacementField[gradientStep,updateFieldMeshSizeAtBaseLevel,totalFieldMeshSizeAtBaseLevel,<splineOrder=3>]
              TimeVaryingVelocityField[gradientStep,numberOfTimeIndices,updateFieldVarianceInVoxelSpace,updateFieldTimeVariance,totalFieldVarianceInVoxelSpace,totalFieldTimeVariance]
              TimeVaryingBSplineVelocityField[gradientStep,velocityFieldMeshSize,<numberOfTimePointSamples=4>,<splineOrder=3>]
              SyN[gradientStep,updateFieldVarianceInVoxelSpace,totalFieldVarianceInVoxelSpace]
              BSplineSyN[gradientStep,updateFieldMeshSizeAtBaseLevel,totalFieldMeshSizeAtBaseLevel,<splineOrder=3>]
              Exponential[gradientStep,updateFieldVarianceInVoxelSpace,velocityFieldVarianceInVoxelSpace,<numberOfIntegrationSteps>]
              BSplineExponential[gradientStep,updateFieldMeshSizeAtBaseLevel,velocityFieldMeshSizeAtBaseLevel,<numberOfIntegrationSteps>,<splineOrder=3>]

              Several   transform   options  are  available.  The  gradientStep  or  learningRate
              characterizes the gradient descent optimization and  is  scaled  appropriately  for
              each  transform  using  the  shift  scales  estimator.  Subsequent  parameters  are
              transform-specific  and  can  be  determined  from  the  usage.  For  the  B-spline
              transforms  one  can  also  specify the smoothing in terms of spline distance (i.e.
              knot spacing).

       -c, --convergence MxNxO
              [MxNxO,<convergenceThreshold=1e-6>,<convergenceWindowSize=10>]

              Convergence is determined from the number of iterations per level and is determined
              by  fitting a line to the normalized energy profile of the last N iterations (where
              N is specified by the window size) and determining the slope which is then compared
              with the convergence threshold.

       -s, --smoothing-sigmas MxNxO...

              Specify  the sigma of gaussian smoothing at each level. Units are given in terms of
              voxels  ('vox')  or  physical  spacing  ('mm').  Example  usage  is  '4x2x1mm'  and
              '4x2x1vox' where no units implies voxel spacing.

       -f, --shrink-factors MxNxO...

              Specify  the  shrink  factor  for the virtual domain (typically the fixed image) at
              each level.

       -u, --use-histogram-matching

              Histogram match the images before registration.

       -l, --use-estimate-learning-rate-once

              turn on the option that lets you estimate the learning rate step size only  at  the
              beginning of each level. * useful as a second stage of fine-scale registration.

       -w, --winsorize-image-intensities [lowerQuantile,upperQuantile]

              Winsorize data based on specified quantiles.

       -x, --masks [fixedImageMask,movingImageMask]

              Image  masks  to limit voxels considered by the metric. Two options are allowed for
              mask specification: 1) Either the user specifies a single mask to be used  for  all
              stages  or  2)  the  user  specifies a mask for each stage. With the latter one can
              select to which stages masks are applied by supplying valid  file  names.   If  the
              file  does  not  exist, a mask will not be used for that stage. Note that we handle
              the fixed and moving masks separately to enforce this constraint.

       --float

              Use 'float' instead of 'double' for computations.  <VALUES>: 0

       --minc

              Use MINC file formats for transformations.  <VALUES>: 0

       -v, --verbose (0)/1

              Verbose output.

       -h

              Print the help menu (short version).

       --help

              Print the help menu. Will also print values used on the current command line  call.
              <VALUES>: 1