Orfeo Toolbox  3.16
Class Hierarchy
This inheritance list is sorted roughly, but not completely, alphabetically:
[detail level 1234567891011]
oCotb::ViewerModel::_ObjectsTracked
oCitk::Function::Abs< TInput, TOutput >
oCitk::Function::Abs< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::HessianToObjectnessMeasureImageFilter< TInputImage, TOutputImage >::AbsCompare
oCitk::Functor::AbsoluteValueDifference2< TInput1, TInput2, TOutput >
oCitk::Functor::AbsoluteValueDifference2< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Accessor::AbsPixelAccessor< TInternalType, TExternalType >Give access to the vcl_abs() function of a value
oCitk::Accessor::AbsPixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::Functor::AccessorFunctor< TInput, TAccessor >Convert an accessor to a functor so that it can be used in a UnaryFunctorImageFilter
oCitk::Functor::AccessorFunctor< TInputImage::PixelType, TAccessor >
oCitk::Functor::Acos< TInput, TOutput >
oCitk::Functor::Acos< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::AcosPixelAccessor< TInternalType, TExternalType >Give access to the vcl_acos() function of a value
oCitk::Accessor::AcosPixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::Functor::Add1< TInput, TOutput >
oCitk::Functor::Add1< TInputImage::PixelType, TInputImage::PixelType >
oCitk::Functor::Add2< TInput1, TInput2, TOutput >
oCitk::Functor::Add2< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Function::Add3< TInput1, TInput2, TInput3, TOutput >
oCitk::Function::Add3< TInputImage1::PixelType, TInputImage2::PixelType, TInputImage3::PixelType, TOutputImage::PixelType >
oCitk::Functor::AddConstantTo< TInput, TConstant, TOutput >
oCitk::Functor::AddConstantTo< TInputImage::PixelType, TConstant, TOutputImage::PixelType >
oCitk::Concept::AdditiveOperators< T1, T2, T3 >
oCitk::Accessor::AddPixelAccessor< TPixel >Simulates the effect of adding a constant value to all pixels
oCitk::Accessor::AddPixelAccessor< TImage::PixelType >
oCotb::Functor::AlphaBlendingFunctorBase< TInputPixel1, TInputPixel2, TOutputPixel >
oCotb::Functor::AlphaBlendingFunctorBase< itk::RGBAPixel< TInputInternalPixel1 >, itk::RGBAPixel< TInputInternalPixel2 >, itk::RGBAPixel< TOutputInternalPixel > >
oCotb::Functor::AmplitudePhaseToRGBFunctor< TInput1, TInput2, TInput3, TOutput >Function object to compute a color representation of a radar image
oCitk::AnchorErodeDilateLine< TInputPix, TFunction1, TFunction2 >Class to implement erosions and dilations using anchor methods. This is the base class that must be instantiated with appropriate definitions of greater, less and so on. There is special code for cases where the structuring element is bigger than the image size that aren't particularly anchor related, but use the same data structures. Hopefully these sections occupy a very minor proportion of the time
oCitk::AnchorOpenCloseLine< TInputPix, THistogramCompare, TFunction1, TFunction2 >Class to implement openings and closings using anchor methods. This is the base class that must be instantiated with appropriate definitions of greater, less and so on
oCAnchorUtilitiesFunctionality in common for anchor openings/closings and erosions/dilation
oCitk::Functor::AND< TInput1, TInput2, TOutput >
oCitk::Functor::AND< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCotb::Wrapper::ApplicationHtmlDocGeneratorThis class genertaes the documentation of a class usung the class doc attributes
oCotb::Wrapper::AppliThread
oCitk::Functor::Asin< TInput, TOutput >
oCitk::Functor::Asin< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::AsinPixelAccessor< TInternalType, TExternalType >Give access to the vcl_asin() function of a value
oCitk::Accessor::AsinPixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::Concept::Assignable< T >
oCotb::Functor::AssociativeSymmetricalSum< TInput1, TInput2, TOutput >Functor used with the AssociativeSymmetricalSumImageFilter
oCotb::Functor::AssociativeSymmetricalSum< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Functor::Atan< TInput, TOutput >
oCitk::Functor::Atan2< TInput1, TInput2, TOutput >
oCitk::Functor::Atan2< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Functor::Atan< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::AtanPixelAccessor< TInternalType, TExternalType >Give access to the vcl_atan() function of a value
oCitk::Accessor::AtanPixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::Functor::AttributeLabelObjectAccessor< TLabelObject >
oCotb::Functor::AttributesMapLabelObjectAccessor< TLabelObject >Allows to acces a given field of an AttributesMapLabelObject
oCotb::Functor::AttributesMapLabelObjectAccessor< TImage::LabelObjectType >
oCotb::Functor::AttributesMapMeasurementFunctor< TLabelObject, TMeasurementVector >This class allows to build a measurement vector from an AttributesMapLabelObject
oCitk::AutoPointer< TObjectType >Implements an Automatic Pointer to an object
oCitk::AuxVarTypeDefault< TPixel, VAuxDimension, VSetDimension >Level set auxiliary variables type information
oCitk::BandNode< TIndexType, TDataType >
oCotb::Functor::BandStatsAttributesLabelObjectFunctor< TLabelObject, TFeatureImage >Functor to compute bands statistics attributes
oCotb::Functor::BandStatsAttributesLabelObjectFunctor< TImage::LabelObjectType, otb::Image< double, 2 > >
oCitk::BarycentricCombination< TPointContainer, TWeightContainer >
oCotb::Functor::BayesianFunctor< TInputMultiSpectral, TInputMultiSpectralInterp, TInputPanchro, TOutput >Functor for the bayesian fusion filter. Please refer to BayesianFusionFilter
oCotb::Functor::BayesianFunctor< TInputMultiSpectralImage::PixelType, TInputMultiSpectralInterpImage::PixelType, TInputPanchroImage::PixelType, TOutputImage::PixelType >
oCitk::Function::BinaryAccumulator< TInputPixel, TOutputPixel >
oCitk::ImageToImageFilterDetail::BinaryBooleanDispatch< B1, B2 >Templated class to produce a unique type for a pairing of booleans
oCitk::Functor::BinaryElongationLabelObjectAccessor< TLabelObject >
oCitk::Functor::BinaryFlatnessLabelObjectAccessor< TLabelObject >
oCitk::ImageToImageFilterDetail::BinaryIntDispatch< D1, D2 >Templated class to produce a unique type for a pairing of integers
oCitk::Functor::BinaryNot< TPixel >
oCitk::Functor::BinaryNot< TImage::PixelType >
oCitk::Functor::BinaryPrincipalAxesLabelObjectAccessor< TLabelObject >
oCitk::Functor::BinaryPrincipalMomentsLabelObjectAccessor< TLabelObject >
oCotb::Functor::BinarySpectralAngleFunctor< TInput1, TInput2, TOutputValue >
oCBinarySpectralAngleFunctorThis functor computes the spectral angle between two pixels
oCitk::Functor::BinaryThreshold< TInput, TOutput >
oCitk::Functor::BinaryThreshold< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Function::BinaryThresholdAccumulator< TInputPixel, TOutputPixel >
oCitk::bioradheader
oCitk::Function::BlackmanWindowFunction< VRadius, TInput, TOutput >Window function for sinc interpolation.

\[ w(x) = 0.42 + 0.5 cos(\frac{\pi x}{m}) + 0.08 cos(\frac{2 \pi x}{m}) \]

oCotb::Function::BlackmanWindowFunction< TInput, TOutput >Window function for sinc interpolation.

\[ w(x) = 0.42 + 0.5 cos(\frac{\pi x}{m}) + 0.08 cos(\frac{2 \pi x}{m}) \]

oCotb::Function::BlackmanWindowFunction< TInputInterpolator, TOutputInterpolator >
oCotb::Functor::BlendingFunctor< TInputPixel1, TInputPixel2, TOutputPixel >Todo
oCotb::Functor::BlendingFunctor< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::BloxItemAn entry in the BloxPixel linked list
oCitk::BloxPixel< TItemType >Holds a linked list of BloxItem's
oCitk::BloxPixel< BloxBoundaryPointItem< NDimensions > >
oCitk::BloxPixel< BloxBoundaryProfileItem< NDimensions > >
oCitk::BloxPixel< BloxCoreAtomItem< NDimensions > >
oCitk::BluePixelAccessor< T >Give access to the Blue component of a RGBPixel type
oCotb::ogr::DataSource::boolean
oCotb::ogr::Layer::booleanint boolean ::* () const
oCitk::ImageToImageFilterDetail::BooleanDispatch< bool >Templated class to produce a unique type "true" and "false"
oCotb::SpectralSensitivityReader::BothAre
oCitk::Mesh< TPixelType, VDimension, TMeshTraits >::BoundaryAssignmentIdentifier
oCitk::Functor::BoundedReciprocal< TInput, TOutput >
oCitk::Functor::BoundedReciprocal< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Concept::BracketOperator< T1, T2, T3 >
oCitk::Brains2HeaderBase
oCitk::Brains2HeaderFactoryCreate instances of Brains2Header objects using an object factory
oCitk::Brains2MaskMappingFunction< TPixel >
oCitk::BresenhamLine< VDimension >
oCitk::BSplineDownsampleImageFilter< TInputImage, TOutputImage, ResamplerType >Down-samples an image by a factor of 2 using B-Spline filter interpolation
oCitk::BSplineUpsampleImageFilter< TInputImage, TOutputImage, ResamplerType >Uses B-Spline interpolation to upsample an image by a factor of 2. This class is the public interface for spline upsampling as defined by the ResamplerType
oCotb::internal::ReprojectTransformationFunctor::ByCopy
oCitk::CacheableScalarFunctionFunction cache implementation
oCitk::NeighborhoodAlgorithm::CalculateOutputWrapOffsetModifiers< TImage >
oCitk::VTKImageExportBase::CallbackTypeProxy
oCitk::Statistics::KdTreeBasedKmeansEstimator< TKdTree >::CandidateVector::Candidate
oCitk::Statistics::KdTreeBasedKmeansEstimator< TKdTree >::CandidateVector
oCitk::CannyEdgeDetectionImageFilter< TInputImage, TOutputImage >::CannyThreadStruct
oCitk::Functor::Cast< TInput, TOutput >
oCitk::Functor::Cast< TImage::PixelType, TImage::PixelType >
oCitk::Functor::Cast< TInputImage::PixelType, TOutputImage::PixelType >
oCCastPixelAccessor
oCotb::Functor::CBAMI< TInput1, TInput2, TOutput >
oCotb::Functor::CBAMI< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType >
oCitk::bio::CellBaseNon-templated Base class from which the templated Cell classes will be derived. Derived classes are instantiated for a specific space dimension
oCitk::CellInterface< TPixelType, TCellTraits >
oCitk::CellTraitsInfo< VPointDimension, TCoordRep, TInterpolationWeight, TPointIdentifier, TCellIdentifier, TCellFeatureIdentifier, TPoint, TPointsContainer, TUsingCellsContainer >A simple utility class to define the cell type inside a mesh type structure definition. This just makes a copy of existing type information that is needed for a cell type template parameter
oCitk::Functor::CenterOfGravityLabelObjectAccessor< TLabelObject >
oCitk::Functor::CentroidLabelObjectAccessor< TLabelObject >
oCitk::Functor::ChangeLabel< TInput, TOutput >
oCitk::Functor::ChangeLabel< TInputImage::PixelType, TOutputImage::PixelType >
oCotb::Wrapper::ChoiceParameter::Choice
oCotb::ClosePathFunctor< TInput, TOutput >This filter close the input path, making the last point equal to the first one
oCotb::Functor::CloudDetectionFunctor< TInput, TOutputValue >
oCCloudDetectionFunctorThis functor first uses CloudEstimatorFunctor
oCotb::Functor::CloudEstimatorFunctor< TInput, TOutputValue >Functor to help with the cloud detection
oCitk::MultivariateLegendrePolynomial::CoefficientVectorSizeMismatch
oCCoherencyToReciprocalMuellerFunctorEvaluate the reciprocal Mueller matrix from the reciprocal coherency matrix image
oCotb::Functor::ColorAnaglyphFunctor< TInputPixel1, TInputPixel2, TOutputPixel >DEPRECATED: This functor implements the pixel-wise color anaglyph composition. The output pixel is a vector pixel of size 3, where the first component contains the value of the first component from the second input pixel, the second component contains the value of the second component from the first input pixel, and the third component contains the value of the third component of the first input pixel
oCotb::Functor::ColorAnaglyphFunctor< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Concept::Comparable< T1, T2 >
oCitk::AttributeKeepNObjectsLabelMapFilter< TImage, TAttributeAccessor >::Comparator
oCitk::AttributeRelabelLabelMapFilter< TImage, TAttributeAccessor >::Comparator
oCitk::AttributeMorphologyBaseImageFilter< TInputImage, TOutputImage, TAttribute, TFunction >::ComparePixStruct
oCitk::Function::ComplexToImaginary< TInput, TOutput >
oCitk::Function::ComplexToImaginary< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::ComplexToImaginaryPixelAccessor< TInternalType, TExternalType >Give access to the Imaginary part of a std::complex<> value
oCitk::Accessor::ComplexToImaginaryPixelAccessor< TImage::PixelType, TOutputPixelType >
oCotb::Function::ComplexToIntensity< TInput, TOutput >
oCotb::Function::ComplexToIntensity< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Function::ComplexToModulus< TInput, TOutput >
oCitk::Function::ComplexToModulus< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::ComplexToModulusPixelAccessor< TInternalType, TExternalType >Give access to the Modulus of a std::complex<> value
oCitk::Accessor::ComplexToModulusPixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::Function::ComplexToPhase< TInput, TOutput >
oCitk::Function::ComplexToPhase< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::ComplexToPhasePixelAccessor< TInternalType, TExternalType >Give access to the Phase part of a std::complex<> value
oCitk::Accessor::ComplexToPhasePixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::Function::ComplexToReal< TInput, TOutput >
oCitk::Function::ComplexToReal< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::ComplexToRealPixelAccessor< TInternalType, TExternalType >Give access to the Real part of a std::complex<> value
oCitk::Accessor::ComplexToRealPixelAccessor< TImage::PixelType, TOutputPixelType >
oCotb::Functor::ComplexToVector< TInput, TOutput >
oCotb::Functor::ComplexToVector< itk::VariableLengthVector< TInput >, TOutput >
oCotb::Functor::ComplexToVector< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Function::Compose2DCovariantVector< TInput >
oCitk::Function::Compose2DCovariantVector< TInputImage::PixelType >
oCitk::Function::Compose2DVector< TInput >
oCitk::Function::Compose2DVector< TInputImage::PixelType >
oCitk::Function::Compose3DCovariantVector< TInput >
oCitk::Function::Compose3DCovariantVector< TInputImage::PixelType >
oCitk::Function::Compose3DVector< TInput >
oCitk::Function::Compose3DVector< TInputImage::PixelType >
oCitk::Function::ComposeRGB< TInput >
oCitk::Function::ComposeRGB< TInputImage::PixelType >
oCitk::Functor::ComposeRGBA< TInput >
oCitk::Functor::ComposeRGBA< TInputImage::PixelType >
oCotb::Functor::ComputeNeighborhoodContributionFunctor< TNeighIter, TOutput >Unary neighborhood functor to compute the value of a pixel which is a sum of the surrounding pixels value ponderated by a coefficient
oCotb::Functor::ComputeNeighborhoodContributionFunctor< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType >
oCotb::Functor::ConcatenateScalarValueFunctor< TInput, TOutput >TODO
oCotb::Functor::ConcatenateScalarValueFunctor< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::ConditionalConstIterator< TImage >ConditionalConstIterator is a base class for other iterators where membership in the set of output pixels is "conditional" upon some property, calculation, etc. For example, a threshold iterator might walk a region and return only those pixels which meet a minimum intensity condition
oCotb::Functor::ConnectedComponentMuParserFunctor< TInput >
oCConnectedComponentMuParserFunctorThis functor use MuParser as criteria for itk connected component module
oCConnectedComponentMuParserFunctorFunctor used as input to itk connected component segmentation module
oCotb::Functor::ConnectedLabelFunctor< TInput >
oCitk::watershed::Segmenter< TInputImage >::connectivity_t
oCitk::ConstShapedNeighborhoodIterator< TImage, TBoundaryCondition >::ConstIterator
oCitk::IndexedContainerInterface< TElementIdentifier, TElement >::ConstIteratorSupport const iteration operations through a container. Dereferencing the iterator must provide an object with the following methods: ElementIdentifier Index(void) const; const Element& Value(void) const;
oCitk::MapContainer< TElementIdentifier, TElement >::ConstIteratorThe const iterator type for the map
oCitk::VectorContainer< TElementIdentifier, TElement >::ConstIterator
oCitk::Statistics::Histogram< TMeasurement, VMeasurementVectorSize, TFrequencyContainer >::ConstIterator
oCitk::Statistics::ImageToListAdaptor< TImage, TMeasurementVector >::ConstIterator
oCitk::Statistics::ListSample< TMeasurementVector >::ConstIterator
oCitk::Statistics::MembershipSample< TSample >::ConstIterator
oCitk::Statistics::PointSetToListAdaptor< TPointSet >::ConstIterator
oCitk::Statistics::Subsample< TSample >::ConstIterator
oCitk::Statistics::VariableDimensionHistogram< TMeasurement, TFrequencyContainer >::ConstIterator
oCotb::ObjectList< TObject >::ConstIteratorConstIterator of the object list
oCitk::Functor::ConstrainedValueAddition< TInput1, TInput2, TOutput >
oCitk::Functor::ConstrainedValueAddition< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Functor::ConstrainedValueDifference< TInput1, TInput2, TOutput >
oCitk::Functor::ConstrainedValueDifference< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Concept::DefaultConstructible< T >::Constraints
oCitk::Concept::Convertible< T1, T2 >::Constraints
oCitk::Concept::Assignable< T >::Constraints
oCitk::Concept::CopyConstructible< T >::Constraints
oCitk::Concept::LessThanComparable< T1, T2 >::Constraints
oCitk::Concept::EqualityComparable< T1, T2 >::Constraints
oCitk::Concept::GreaterThanComparable< T1, T2 >::Constraints
oCitk::Concept::Comparable< T1, T2 >::Constraints
oCitk::Concept::AdditiveOperators< T1, T2, T3 >::Constraints
oCitk::Concept::MultiplyOperator< T1, T2, T3 >::Constraints
oCitk::Concept::MultiplyAndAssignOperator< T1, T2 >::Constraints
oCitk::Concept::DivisionOperators< T1, T2, T3 >::Constraints
oCitk::Concept::LogicalOperators< T1, T2, T3 >::Constraints
oCitk::Concept::BracketOperator< T1, T2, T3 >::Constraints
oCitk::Concept::NotOperator< T >::Constraints
oCitk::Concept::IncrementDecrementOperators< T >::Constraints
oCitk::Concept::OStreamWritable< T >::Constraints
oCitk::Concept::Signed< T >::Constraints
oCitk::Concept::SameType< T1, T2 >::Constraints
oCitk::Concept::SameDimension< D1, D2 >::Constraints
oCitk::Concept::HasNumericTraits< T >::Constraints
oCitk::Concept::HasPixelTraits< T >::Constraints
oCitk::Concept::HasValueType< T >::Constraints
oCitk::Concept::HasZero< T >::Constraints
oCitk::Concept::HasJoinTraits< T1, T2 >::Constraints
oCitk::Concept::IsInteger< T >::Constraints
oCitk::Concept::SameDimensionOrMinusOne< D1, D2 >::Constraints
oCitk::Concept::IsNonInteger< T >::Constraints
oCitk::Concept::IsFloatingPoint< T >::Constraints
oCitk::Concept::IsFixedPoint< T >::Constraints
oCitk::FixedArray< TValueType, VLength >::ConstReverseIteratorA const reverse iterator through the array
oCitk::ConstSliceIterator< TPixel, TContainer >A flexible iterator for itk containers(i.e. itk::Neighborhood) that support pixel access through operator[]
oCitk::ConstSparseFieldLayerIterator< TNodeType >
oCitk::ContourExtractor2DImageFilter< TInputImage >::ContourType
oCitk::bio::Gene::ControlDomainType
oCitk::Concept::Convertible< T1, T2 >
oCitk::ConvertPixelBuffer< InputPixelType, OutputPixelType, OutputConvertTraits >Class to convert blocks of data from one type to another
oCotb::Functor::ConvexOrConcaveDecisionRule< TInput, TOutput >This functor labels the given pixel between three classes Convex, Concave and Flat
oCotb::Functor::ConvexOrConcaveDecisionRule< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Functor::JoinFunctor< TPixel1, TPixel2 >::CopierDispatchBase
oCitk::Concept::CopyConstructible< T >
oCotb::CorrectPolygonFunctor< TPolygon >This filter simplify and close the input polygon, making the last point equal to the first one
oCitk::CorrespondenceDataStructureIterator< TStructureType >An iterator designed to easily traverse an itkCorrespondenceDataStructure
oCitk::CorrespondingList< TItemType, VCliqueSize >Part of the itkCorrespondenceDataStructure
oCitk::CorrespondingMedialNodeClique< VImageDimension, VCliqueSize >CorrespondingMedialNodeClique is an item stored in CorrespondingNodeList. Specifically it is stored in corresponding node lists and contain pointers to a set of medial nodes (cliques)
oCitk::Functor::Cos< TInput, TOutput >
oCitk::Functor::Cos< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Function::CosineWindowFunction< VRadius, TInput, TOutput >Window function for sinc interpolation.

\[ w(x) = cos(\frac{\pi x}{2 m} ) \]

oCotb::Function::CosineWindowFunction< TInput, TOutput >
oCotb::Function::CosineWindowFunction< TInputInterpolator, TOutputInterpolator >
oCitk::Accessor::CosPixelAccessor< TInternalType, TExternalType >Give access to the vcl_cos() function of a value
oCitk::Accessor::CosPixelAccessor< TImage::PixelType, TOutputPixelType >
oCotb::Count< TPointSet, TRadiusType, TIndexType >Compute the density of a neighboorhood centerred in a pixel
oCotb::ogr::internal::CppToOGRConverter_trait< T >Trait class for converting C++ types into OGR field setter compatible types
oCotb::ogr::internal::CppToOGRConverter_trait< std::string >Specialisation for C++ std::string
oCotb::ogr::internal::CppToOGRConverter_trait< T[N]>Specialisation for C static arrays
oCCrossCompute the cross product of two vectors of dimension 3, independently of the type of the values of vector's elements
oCotb::Functor::CrossCorrelation< TInput1, TInput2, TOutput >Functor to compute the cross correlation
oCotb::Functor::CrossCorrelation< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType >
oCitk::CrossHelper< TVector >
oCotb::CumulantsForEdgeworth< TInput >Helper class for KullbackLeiblerDistanceImageFilter. Please refer to KullbackLeiblerDistanceImageFilter
oCotb::CumulantsForEdgeworth< ROIInputType1 >
oCotb::CumulantsForEdgeworth< ROIInputType2 >
oCotb::CumulantsForEdgeworthProfile< TInput >Helper class for KullbackLeiblerProfileImageFilter. Please refer to KullbackLeibleProfileImageFilter
oCotb::Functor::CzihoSOMLearningBehaviorFunctorBeta behavior over SOM training phase
oCotb::Functor::CzihoSOMNeighborhoodBehaviorFunctorNeighborhood size behavior over SOM training phase
oCotb::DataSpecThis struct contains the specific absorption coefficients of each constituent and the refractive index of leaf materia
oCotb::DataNode< TPrecision, VDimension, TValuePrecision >::DataType
oCotb::internal::Date
oCitk::Concept::DefaultConstructible< T >
oCitk::DefaultConvertPixelTraits< PixelType >Traits class used to by ConvertPixels to convert blocks of pixels
oCotb::DefaultDescriptorsType< TOutputPrecision >
oCotb::DefaultDescriptorType< TFunctionPrecision >
oCitk::DefaultDynamicMeshTraits< TPixelType, VPointDimension, VMaxTopologicalDimension, TCoordRep, TInterpolationWeight, TCellPixelType >
oCitk::DefaultImageTraits< TPixelType, VImageDimension, TPixelContainer >Default ImageTraits for any PixelType
oCitk::DefaultPixelAccessor< TType >Give access to partial aspects a type
oCitk::DefaultPixelAccessorFunctor< TImageType >This class provides a common API for pixel accessors for Image and VectorImage. (between the DefaultVectorPixelAccessor and DefaultPixelAccessor)
oCitk::DefaultStaticMeshTraits< TPixelType, VPointDimension, VMaxTopologicalDimension, TCoordRep, TInterpolationWeight, TCellPixelType >
oCitk::DefaultVectorPixelAccessor< TType >Give access to partial aspects of a type
oCitk::DefaultVectorPixelAccessorFunctor< TImageType >This class provides a common API for pixel accessors for Image and VectorImage. (between the DefaultVectorPixelAccessor and DefaultPixelAccessor)
oCDeformableMesh3DThe DeformableMesh3DFilter is used to deform a mesh (deformable model) under a potential force in 2D or 3D. The potential force is derived from the gradient information in the medical image and it will make the model deform to fit to the boundary features
oCinternal::Deleters
oCitk::DenseFiniteDifferenceImageFilter< TInputImage, TOutputImage >::DenseFDThreadStruct
oCitk::MovingHistogramImageFilterBase< TInputImage, TOutputImage, TKernel >::DirectionCost
oCitk::BSplineKernelFunction< VSplineOrder >::DispatchBase
oCitk::ImageToImageFilterDetail::DispatchBaseBase class for a class used to dispatch to dimension specific implementations
oCitk::MinMaxCurvatureFlowFunction< TImage >::DispatchBase
oCitk::FlatStructuringElement< VDimension >::DispatchBase
oCitk::LinearInterpolateImageFunction< TInputImage, TCoordRep >::DispatchBase
oCotb::Functor::DistanceComparisonFunctorThis functor is used in nearest neighborhood sorting
oCitk::Function::Div< TInput1, TInput2, TOutput >
oCitk::Function::Div< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Functor::DivideByConstant< TInput, TConstant, TOutput >
oCitk::Functor::DivideByConstant< TInputImage::PixelType, TConstant, TOutputImage::PixelType >
oCitk::Concept::DivisionOperators< T1, T2, T3 >
oCotb::Functor::DotProductFunctor< TInput, TOutput >Computes the dot product against a specific vector
oCotb::Functor::DotProductFunctor< TInputImage::PixelType, TOutputImage::PixelType >
oCotb::ogr::Drivers
oCitk::fem::FEMObjectFactory< T >::DummyThis class is defined in FEMObjectFactory just to get rid of some warnings about destructor being private in gcc
oCitk::watershed::SegmentTable< TScalarType >::edge_pair_t
oCitk::Functor::EdgePotential< TInput, TOutput >
oCitk::Functor::EdgePotential< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::fem::Element1DStress< TBaseClass >Class that is used to define linear elasticity problem in 1D space
oCitk::fem::Element2DMembrane< TBaseClass >Class that is used to define a membrane energy problem in 2D space
oCitk::fem::Element2DStrain< TBaseClass >Class that is used to define linear elasticity problem in 2D space
oCitk::fem::Element2DStress< TBaseClass >Class that is used to define linear elasticity problem in 2D space
oCitk::fem::Element3DMembrane< TBaseClass >Class that is used to define a membrane energy problem in 3D space
oCitk::fem::Element3DStrain< TBaseClass >Class that is used to define linear elasticity problem in 3D space
oCitk::fem::ElementStd< VNumberOfNodes, VNumberOfSpatialDimensions, TBaseClass >Implements standard node management in the element classes
oCitk::ElementWrapperInterface< TElement, TElementIdentifier >
oCitk::ElementWrapperInterface< MinPriorityQueueElementWrapper< TElement, TElementPriority, TElementIdentifier >, TElementIdentifier >
oCitk::ElementWrapperPointerInterface< TElementWrapperPointer, TElementIdentifier >
oCotb::Wrapper::ElevationParametersHandlerThis class represent a helper class for elevation modes. It add the parameters automatically to the application where it is used, provide method to get the value needed
oCEllipsoidSpatialFunctionFunction implementation of an ellipsoid
oCEllipsoidSpatialFunctionFunction implementation of an ellipsoid
oCitk::Functor::ElongationLabelObjectAccessor< TLabelObject >
oCotb::ogr::DataSource::layer_iter< Value >::enabler
oCotb::ogr::Layer::feature_iter< Value >::enabler
oCotb::Functor::EnvelopeSavitzkyGolayInterpolationFunctor< Radius, TSeries, TDates, TWeight >
oCitk::Concept::EqualityComparable< T1, T2 >
oCitk::Functor::EquivalentEllipsoidSizeLabelObjectAccessor< TLabelObject >
oCitk::Functor::EquivalentPerimeterLabelObjectAccessor< TLabelObject >
oCitk::Functor::EquivalentRadiusLabelObjectAccessor< TLabelObject >
oCErrorBackPropagationLearningFunctionBaseThe ErrorBackPropagationLearningFunctionBase is the base class for all the ErrorBackPropagationLearning strategies. These include error back propagation, bp+momentum, conjugte gradient descent, quick prop. This class specifies how the errors are backpropagated for a layer. They take a LayerBase object as input and compute the input for the layers input weightset
oCErrorBackPropagationLearningWithMomentumThe ErrorBackPropagationLearningWithMomentum is the base class for all the ErrorBackPropagationLearning strategies. These include error back propagation, bp+momentum, conjugte gradient descent, quick prop. This class specifies how the errors are backpropagated for a layer. They take a LayerBase object as input and compute the input for the layers input weightset
oCEulerOperatorCreateCenterVertexFunctionCreate a vertex at the barycenter of the given face
oCEulerOperatorDeleteCenterVertexFunctionDelete the vertex, connected edges and faces and create a new face In place of the previous vertex' one-ring
oCEulerOperatorFlipEdgeFunctionFlip an edge
oCEulerOperatorJoinFacetFunctionJoin the two facets which are on both sides of a given internal edge
oCEulerOperatorJoinVertexFunctionCollapse a given edge by joining its dest and its org
oCEulerOperatorSplitEdgeFunctionGiven Edge is splitted into two and associated faces see their degree increased by one (a triangle is transformed into a quad for example)
oCEulerOperatorSplitFacetFunctionGiven two edges h and g sharing the same Left() face, create a new edge joining h->Destination() to g->Destination(), thus splitting the original Left()
oCEulerOperatorSplitVertexFunctionFor two given edges e and f sharing the same dest(), disconnect the two rings, create a new point to be set at f->dest(), and create a new edge between e->Destination() and f->Destination()
oCitk::EventObjectAbstraction of the Events used to communicating among filters and with GUIs
oCitk::ExceptionObjectStandard exception handling object
oCitk::Function::Exp< TInput, TOutput >
oCitk::Function::Exp< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Function::ExpNegative< TInput, TOutput >
oCitk::Function::ExpNegative< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Accessor::ExpNegativePixelAccessor< TInternalType, TExternalType >Give access to the vcl_exp() function of a value
oCitk::Accessor::ExpNegativePixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::Accessor::ExpPixelAccessor< TInternalType, TExternalType >Give access to the vcl_exp() function of a value
oCitk::Accessor::ExpPixelAccessor< TImage::PixelType, TOutputPixelType >
oCitk::watershed::Boundary< TScalarType, TDimension >::face_pixel_t
oCitk::FiniteDifferenceSparseImageFilter< TInputImageType, TSparseOutputImageType >::FDThreadStruct
oCotb::ogr::FeatureGeometric objet with descriptive fields
oCotb::ogr::Layer::feature_iter< Value >Implementation class for Feature iterator. This iterator is a single pass iterator. We may fetch the Feature referenced by an iterator previously stored, but never resume the iteration after a call to Layer::begin(), Layer::start_at(), Layer::CreateFeature(), Layer::DeleteFeature(), Layer::GetFeature(), Layer::SetFeature(), nor fork the iteration
oCotb::OGRLayerStreamStitchingFilter< TInputImage >::FeatureStruct
oCitk::MRCHeaderObject::FeiExtendedHeader
oCitk::fem::FEMInitializationFEM Library initialization and housekeeping
oCitk::fem::FEMLightObjectBase class for all classes that define the FEM system
oCitk::fem::FEMObjectFactory< T >Create objects of derived classes by specifying a class ID
oCitk::fem::FEMObjectFactory< FEMLightObject >
oCitk::fem::FEMP< T >Pointer used to store polymorphic elements in STL arrays
oCitk::fem::FEMPArray< T >Array for FEMP objects
oCitk::Functor::FeretDiameterLabelObjectAccessor< TLabelObject >
oCotb::ogr::FieldEncapsulation of OGRField Instances of Field are expected to be built from an existing Feature with which they'll share their owning OGRFeature
oCotb::FieldCopyTransformation
oCotb::ogr::FieldDefnEncapsulation of OGRFieldDefn: field definition
oCitk::ProgressAccumulator::FilterRecord
oCotb::FilterWatcherBaseThis class is an abstract class Provides an interface to progress task mechanic
oCitk::FixedArray< TValueType, VLength >Simulate a standard C array with copy semnatics
oCitk::FixedArray< CoordRepType, NPointDimension >
oCitk::FixedArray< double, NPointDimension >
oCitk::FixedArray< float, NPointDimension >
oCitk::FixedArray< PointValueType, NPointDimension >
oCitk::FixedArray< SpacingValueType, NVectorDimension >
oCitk::FixedArray< T, NVectorDimension >
oCitk::FixedArray< TComponent, 3 >
oCitk::FixedArray< TComponent, 4 >
oCitk::FixedArray< TComponent, NDimension *(NDimension+1)/2 >
oCitk::FixedArray< TCoordRep, NPointDimension >
oCitk::FixedArray< TInternalImageFunctionType::CoordRepType, NPointDimension >
oCitk::FixedArray< TOutput, NPointDimension >
oCitk::FixedArray< TScalarType, NPointDimension >
oCitk::FixedArray< Type, NPointDimension >
oCFixedImageSamplePoint
oCFixedImageSpatialSample
oCitk::watershed::Boundary< TScalarType, TDimension >::flat_region_t
oCitk::watershed::Segmenter< TInputImage >::flat_region_t
oCitk::Functor::FlatnessLabelObjectAccessor< TLabelObject >
oCFlusserMomentsFFactoryAdd a FlusserMoments image function to a MetaImageFunction
oCitk::VoronoiDiagram2DGenerator< TCoordType >::FortuneEdge
oCitk::VoronoiDiagram2DGenerator< TCoordType >::FortuneHalfEdge
oCitk::VoronoiDiagram2DGenerator< TCoordType >::FortuneSite
oCFourierMellinDescriptorsFFactoryAdd a FourierMellinDescriptors image function to a MetaImageFunction
oCitk::QuadEdgeMeshFrontBaseIterator< TMesh, TQE >::FrontAtomAtomic information associated to each edge of the front
oCotb::SimpleRcsPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >::FusionFunctor
oCFusionFunctor
oCotb::LmvmPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >::FusionFunctor1
oCotb::LmvmPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >::FusionFunctor2
oCotb::OGRLayerStreamStitchingFilter< TInputImage >::FusionStruct
oCotb::FuzzyDescriptorsModelManagerRead a xml file where are stored several statistics
oCotb::Functor::GAndRAndNirIndexBase< TInput1, TInput2, TInput3, TOutput >Base class for Green And Red And NIR channels of Spot Images
oCotb::Functor::GAndRIndexBase< TInput1, TInput2, TOutput >Base class for Green And Red channels of Spot Images XS1 corresponds to the green channel XS2 corresponds to the red channel XS3 corresponds to the Nir channel XS4 corresponds to the Mir channel (for Spot 4 & 5) Implement operators for UnaryFunctorImageFilter templated with a VectorImage and BinaryFunctorImageFilter templated with single images. Subclasses should NOT overload operators, they must re-implement the Evaluate() method
oCotb::Function::GaussianWindowFunction< TInput, TOutput >Gaussian interpolation windowing function.

\[ w(x) = exp ( -2. \frac{sigma*sigma * \pi } ) \]

oCotb::Function::GaussianWindowFunction< TInputInterpolator, TOutputInterpolator >
oCitk::fem::GaussIntegrateUse the Gauss-Legendre formula to perform integration
oCotb::GDALDataTypeWrapper
oCotb::GDALDriverManagerWrapperProvide an unique instance of a GDALDataSet
oCGEImageHeader
oCitk::bio::GeneThis class implement the abstraction of a biological gene
oCitk::bio::GeneNetworkThis class implement the abstraction of a biological gene network
oCitk::GenericCUBFileAdaptorReader and Writer for the VoxBo file format
oCGenericKernelFunctorBaseUndocumented
oCitk::bio::GenomeThis class implement the abstraction of a biological genome
oCotb::ogr::internal::GeometryDeleter
oCitk::Statistics::GetAdaptorMeasurementVectorLength< TAdaptor >
oCitk::GetDimension< T >
oCitk::Statistics::GetHistogramDimension< THistogram >
oCitk::GetImageDimension< TImage >
oCitk::GetMeshDimension< TMesh >
oCitk::GetPointSetDimension< TPointSet >
oCitk::GetVectorDimension< TVector >
oCitk::GiplImageIOInternals
oCotb::GISTableFunction< TInputTable, TOutput >Evaluates a const transaction on a GISTable
oCotb::NCCRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::LevelSetFunction< TImageType >::GlobalDataStruct
oCitk::DemonsRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::FastSymmetricForcesDemonsRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::LevelSetMotionRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::MeanSquareRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::MIRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::ESMDemonsRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::NCCRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::SymmetricForcesDemonsRegistrationFunction< TFixedImage, TMovingImage, TDeformationField >::GlobalDataStruct
oCitk::RegionBasedLevelSetFunction< TInput, TFeature, TSharedData >::GlobalDataStruct
oCitk::Functor::GradientMagnitude< TInput, TOutput >
oCitk::Functor::GradientMagnitude< TInputImage::PixelType, TOutputImage::PixelType >
oCotb::Functor::GrayscaleAnaglyphFunctor< TInputPixel1, TInputPixel2, TOutputPixel >DEPRECATED: This functor implements the pixel-wise grayscale anaglyph composition. The output pixel is a vector pixel of size 3, where the first component contains the value of the first input pixel, and the two last components contain the value of the second input pixel
oCotb::Functor::GrayscaleAnaglyphFunctor< TInputImage1::PixelType, TInputImage2::PixelType, TOutputImage::PixelType >
oCitk::Concept::GreaterThanComparable< T1, T2 >
oCitk::GreenPixelAccessor< T >Give access to the Green component of a RGBPixel type
oCitk::AttributeMorphologyBaseImageFilter< TInputImage, TOutputImage, TAttribute, TFunction >::GreyAndPos
oCGroup
oCitk::Function::HammingWindowFunction< VRadius, TInput, TOutput >Window function for sinc interpolation.

\[ w(x) = 0.54 + 0.46 cos(\frac{\pi x}{m} ) \]

oCotb::Function::HammingWindowFunction< TInput, TOutput >Window function for sinc interpolation.

\[ w(x) = 0.54 + 0.46 cos(\frac{\pi x}{m} ) \]

oCotb::Function::HammingWindowFunction< TInputInterpolator, TOutputInterpolator >
oCHaralickTexturesFFactoryAdd a HaralickTextures image function to a MetaImageFunction
oCitk::hash< Key >
oCitk::hash< char * >
oCitk::hash< char >
oCitk::hash< const char * >
oCitk::hash< int >
oCitk::hash< long >
oCitk::hash< short >
oCitk::hash< signed char >
oCitk::hash< unsigned char >
oCitk::hash< unsigned int >
oCitk::hash< unsigned long >
oCitk::hash< unsigned short >
oCitk::hash_map< Key, T,,, >Replacement for STL hash map because some systems do not support it, or support it incorrectly
oCitk::hash_multimap< Key, T,,, >
oCitk::hash_multiset< Value,,, >
oCitk::hash_set< Value,,, >Replacement for STL hash set because some systems do not support it, or support it incorrectly
oCitk::hashtable_base< Value, Alloc >
oCitk::hashtable_const_iterator< Value, Key, HashFcn, ExtractKey, EqualKey, Alloc >
oCitk::hashtable_iterator< Value, Key, HashFcn, ExtractKey, EqualKey, Alloc >
oCitk::hashtable_node< Value >
oCitk::Concept::HasJoinTraits< T1, T2 >
oCitk::Concept::HasNumericTraits< T >
oCitk::Concept::HasPixelTraits< T >
oCitk::Concept::HasValueType< T >
oCitk::Concept::HasZero< T >
oCitk::MRCHeaderObject::Header
oCHelper
oCotb::Functor::HessianDeterminant< TInput, TOutput >This functor computes the determinant of symmetric 2*2 matrix
oCotb::Functor::HessianToScalar< TInput, TOutput >
oCotb::Functor::HessianToScalar< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::HexahedronCellTopology
oCotb::Functor::HillShadeModulationFunctor< TInput1, TInput2, TOutput >Modulate an image with hill shading
oCotb::Functor::HillShadingFunctor< TNeighIter, TInputImage, TOutput >Unary neighborhood functor to compute the lambertian of a surface
oCotb::Functor::HillShadingFunctor< itk::ConstNeighborhoodIterator< TInputImage >, TInputImage, TOutputImage::PixelType >
oCitk::Function::HistogramEntropyFunction< TInput, TOutput >
oCitk::Function::HistogramEntropyFunction< unsigned long, TOutputPixel >
oCitk::Function::HistogramIntensityFunction< TInput, TOutput >
oCitk::Function::HistogramIntensityFunction< unsigned long, TOutputPixel >
oCitk::Functor::HistogramLabelObjectAccessor< TLabelObject >
oCitk::Function::HistogramLogProbabilityFunction< TInput, TOutput >
oCitk::Function::HistogramLogProbabilityFunction< unsigned long, TOutputPixel >
oCitk::Function::HistogramProbabilityFunction< TInput, TOutput >
oCitk::Function::HistogramProbabilityFunction< unsigned long, TOutputPixel >
oCotb::Functor::HorizontalSobelOperator< TInput, TOutput >Performs the calculation of horizontal Sobel derivation
oCotb::Functor::HorizontalSobelOperator< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType >
oCotb::Functor::HSVToRGBFunctor< TRGBPixel >Function object to convert HSV value to RGB
oCitk::ICDirect
oCitk::ICInverse
oCitk::AutomaticTopologyMeshSource< TOutputMesh >::IdentifierArrayEqualsFunction
oCitk::AutomaticTopologyMeshSource< TOutputMesh >::IdentifierArrayHashFunction
oCotb::Function::Identity< TInputPixel, TOutputPixel >Default math functor parameter for rendering function
oCitk::image_info_defV3
oCitk::image_info_defV4
oCotb::Functor::ImageAndVectorImageOperationFunctor< TInput, TVectorInput, TOutput >
oCotb::Functor::ImageAndVectorImageOperationFunctor< TInputImage::PixelType, TVectorInputImage::PixelType, TOutputImage::PixelType >
oCitk::ImageBoundaryCondition< TImageType >A virtual base object that defines an interface to a class of boundary condition objects for use by neighborhood iterators
oCitk::ImageBoundaryCondition< ImageType >
oCitk::ImageBoundaryCondition< TDeformationField >
oCitk::ImageBoundaryCondition< TImage >
oCitk::ImageBoundaryCondition< TInput >
oCitk::ImageBoundaryCondition< TInputImage >
oCitk::ImageBoundaryCondition< TSparseImageType >
oCitk::NeighborhoodAlgorithm::ImageBoundaryFacesCalculator< TImage >
oCitk::ImageConstIterator< TImage >A multi-dimensional image iterator templated over image type
oCitk::ImageConstIteratorWithIndex< TImage >A base class for multi-dimensional iterators templated over image type that are designed to efficiently keep track of the iterator position
oCitk::ImageConstIteratorWithIndex< TImageType >
oCotb::ImageToOSMVectorDataGenerator< TImage >::ImageExtentType
oCImageFileWriterExceptionBase exception class for IO problems during writing
oCitk::ImageHelper< NImageDimension, NLoop >Fast Index/Offset computation
oCImageIOFactoryCreate instances of ImageIO objects using an object factory
oCitk::ImageIORegionAdaptor< VDimension >Helper class for converting ImageRegions into ImageIORegions and back
oCitk::Statistics::ImageJointDomainTraits< TImage >This class provides the type defintion for the measurement vector in the joint domain (range domain – pixel values + spatial domain – pixel's physical coordinates)
oCotb::ImageKeywordlistStorage and conversion for OSSIM metadata
oCotb::ImageLayerRenderingModelListener
oCitk::fem::ImageMetricLoadImplementation< TLoadClass >
oCotb::ogr::ImageReference< TPrecision >
oCitk::ImageToImageFilterDetail::ImageRegionCopier< D1, D2 >Function object used to dispatching to a routine to copy a region (start index and size)
oCitk::ImageToImageFilterDetail::ImageRegionCopier< T1, T2 >
oCitk::ImageReverseConstIterator< TImage >Multi-dimensional image iterator
oCotb::Functor::ImageToLuminanceImageFunctor< TInput, TOutput >Add beta to the quotient Input over alpha
oCotb::Functor::ImageToReflectanceImageFunctor< TInput, TOutput >Call the ImageToLuminanceFunctor over the input and the LuminanceToReflectanceFunctor to this result
oCitk::ImageTransformHelper< NImageDimension, R, C >Fast index/physical index computation
oCitk::ImageVoxel
oCotb::Function::ImaginaryToComplex< TInputImageImaginaryPart, TOutput >
oCotb::Function::ImaginaryToComplex< TInputImageImaginaryPart::PixelType, TOutputImage::PixelType >
oCitk::Concept::IncrementDecrementOperators< T >
oCitk::IndentControl indentation during Print() invocation
oCitk::Index< VIndexDimension >Represent a n-dimensional index in a n-dimensional image
oCitk::Index< itkGetStaticConstMacro(Dimension)>
oCitk::Index< itkGetStaticConstMacro(ImageDimension) >
oCitk::Index< VDimension >
oCitk::Functor::IndexLexicographicCompare< VIndexDimension >Order Index instances lexicographically
oCitk::fem::INITClassClass that is used in FEM_CLASS_INIT macro
oCotb::internal::ReprojectTransformationFunctor::InPlace
oCitk::Functor::IntensityLinearTransform< TInput, TOutput >
oCitk::Functor::IntensityLinearTransform< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::Functor::IntensityWindowingTransform< TInput, TOutput >
oCitk::Functor::IntensityWindowingTransform< TInputImage::PixelType, TOutputImage::PixelType >
oCInterfaceWrapper for FFTW API
oCitk::InternalHeader
oCitk::IntervalCalculator< PixelType, TOperation >
oCInvalidRequestRegionError
oCitk::Functor::InvertBinaryIntensityFunctor< InputPixelType >
oCitk::Functor::InvertIntensityFunctor< InputPixelType >
oCitk::Functor::InvertIntensityTransform< TInput, TOutput >
oCitk::Functor::InvertIntensityTransform< TInputImage::PixelType, TOutputImage::PixelType >
oCitk::IOCommonCentralized funtionality for IO classes
oCitk::IPLFileNameList– stores filename+info to be enumerated for IPLCommonImageIO
oCitk::IPLFileSortInfo
oCitk::IPLFileSortInfo_ascend_compare
oCitk::IPLFileSortInfo_ascendbyname_compare
oCitk::IPLFileSortInfo_descend_compare
oCitk::IPLFileSortInfo_descendbyname_compare
oCIPLSortInfo– holds info on one file for IPLCommonImageIO
oCboost::is_contiguous< Range >Type-traits: are the elements contiguous in the range
oCboost::is_contiguous< boost::array< T, N > >
oCboost::is_contiguous< boost::ptr_array< T, N, TCA > >
oCboost::is_contiguous< boost::ptr_vector< T, TCA, TA > >
oCboost::is_contiguous< std::vector< T, TAllocator > >
oCitk::Concept::IsFixedPoint< T >
oCitk::Concept::IsFloatingPoint< T >
oCitk::Concept::IsInteger< T >
oCitk::Concept::IsNonInteger< T >
oCotb::Functor::ISRAUnmixingFunctor< TInput, TOutput, TPrecision >TODO
oCotb::Functor::ISRAUnmixingFunctor< TInputImage::PixelType, TOutputImage::PixelType, TPrecision >
oCotb::ogr::internal::IsSetTester
oCitk::IterationReporterImplements iterations tracking for a filter
oCitk::IndexedContainerInterface< TElementIdentifier, TElement >::IteratorSupport iteration operations through a container. Dereferencing the iterator must provide an object with the following methods: ElementIdentifier Index(void) const; Element& Value(void);
oCitk::MapContainer< TElementIdentifier, TElement >::IteratorThe non-const iterator type for the map
oCitk::Statistics::Histogram< TMeasurement, VMeasurementVectorSize, TFrequencyContainer >::Iterator
oCitk::Statistics::ImageToListAdaptor< TImage, TMeasurementVector >::Iterator
oCitk::Statistics::ListSample< TMeasurementVector >::Iterator
oCitk::Statistics::PointSetToListAdaptor< TPointSet >::Iterator
oCitk::Statistics::Subsample< TSample >::Iterator
oCitk::Statistics::VariableDimensionHistogram< TMeasurement, TFrequencyContainer >::Iterator
oCitk::VectorContainer< TElementIdentifier, TElement >::Iterator
oCotb::ObjectList< TObject >::IteratorIterator of the object list
oCitk_jpeg_error_mgr
oCitk_simple_alloc< T, Alloc >
oCitkBSplineCenteredL2ResampleImageFilterBaseUses the "Centered L2" B-Spline pyramid implementation of B-Spline Filters to up/down sample an image by a factor of 2
oCitk::fem::ItpackSparseMatrixCompressed row sparse matrix representation that makes use of itpack to dynamically assemble the matrix
oCitk::Functor::JoinFunctor< TPixel1, TPixel2 >Join the components of two pixel types into a single pixel type
oCotb::Functor::JoinHistogramMI< TInput1, TInput2, TOutput >
oCotb::Functor::JoinHistogramMI< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType >
oCotb::JPEG2000InternalReader
oCotb::JPEG2000MetadataReader
oCotb::JPEG2000TileCache
oCitk::JPEGFileWrapper
oCitk::KalmanLinearEstimator< T, VEstimatorDimension >Implement a linear recursive estimator
oCitk::Statistics::KdTreeNode< TSample >This class defines the interface of its derived classes
oCotb::Meanshift::KernelGaussian
oCotb::Meanshift::KernelUniform
oCotb::MetaDataKey::KeyTypeDef
oCitk::KLMDynamicBorderArray< TBorder >Object maintaining a reference to a list of borders associated with a region
oCotb::Functor::KullbackLeiblerDistance< TInput1, TInput2, TOutput >Functor for KullbackLeiblerDistanceImageFilter. Please refer to KullbackLeiblerDistanceImageFilter
oCotb::Functor::KullbackLeiblerDistance< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType >
oCotb::Functor::KullbackLeiblerProfile< TInput1, TInput2, TOutput >Functor for KullbackLeiblerProfileImageFilter. Please refer to KullbackLeiblerProfileImageFilter
oCotb::Functor::KullbackLeiblerProfile< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType >
oCotb::Functor::KullbackLeiblerSupervizedDistance< TInput1, TInput2, TInputROIImage, TOutput >Functor for KullbackLeiblerSupervizedDistanceImageFilter. Please refer to KullbackLeiblerSupervizedDistanceImageFilter
oCotb::Functor::KullbackLeiblerSupervizedDistance< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TInputROIImage, TOutputImage::PixelType >
oCitk::Functor::KurtosisLabelObjectAccessor< TLabelObject >
oCotb::LabeledOutputAccessor< TFilter >Accessor to the index of the labeled output image of the Template Filter
oCotb::LabeledOutputAccessor< MeanShiftImageFilter< TInputImage, TOutputImage, TLabeledImage, TBufferConverter > >
oCotb::LabeledOutputAccessor< MeanShiftSmoothingImageFilter< TInputImage, TOutputImage, TOutputImage2, TKernelType > >
oCotb::LabeledOutputAccessor< MeanShiftVectorImageFilter< TInputImage, TOutputImage, TLabeledImage > >
oCitk::LabelGeometryImageFilter< TLabelImage, TIntensityImage >::LabelGeometryGeometry stored per label
oCitk::Functor::LabelLabelObjectAccessor< TLabelObject >
oCitk::Functor::LabelObjectComparator< TLabelObject, TAttributeAccessor >
oCotb::Functor::LabelObjectFieldsFunctor< TLabelObject >Returns additionnal OGR fields to be saved in VectorData
oCitk::LabelObjectLine< VImageDimension >
oCitk::Functor::LabelObjectLineComparator< TLabelObjectLine >
oCLabelObjectLineComparatorPerforms a comparison of l1 < l2. Returns true if l1 is strictly less than l2
oCLabelObjectOpeningMuParserImageFilterLabel Object opening using shape and radiometric attributes. Acception/rejection criteria is user defined via MuParser function
oCitk::Functor::LabelObjectReverseComparator< TLabelObject, TAttributeAccessor >
oCotb::Functor::LabelObjectToPolygonFunctor< TLabelObject, TPolygon >This class vectorizes a LabelObject to a Polygon
oCotb::Functor::LabelObjectWithClassLabelFieldsFunctor< TLabelObject >Returns additionnal OGR fields to be saved in VectorData
oCitk::Functor::LabelOverlayFunctor< TInputPixel, TLabel, TRGBPixel >Functor for applying a colormap to a label image and combine it with a grayscale image
oCitk::Functor::LabelOverlayFunctor< TInputImage::PixelType, TLabelImage::PixelType, TOutputImage::PixelType >
oCitk::LabelStatisticsImageFilter< TInputImage, TLabelImage >::LabelStatisticsStatistics stored per label
oCitk::Functor::LabelToRGBFunctor< TLabel, TRGBPixel >Functor for converting labels into RGB triplets
oCitk::Functor::LabelToRGBFunctor< TLabelImage::PixelType, TOutputImage::PixelType >
oCitk::Function::LanczosWindowFunction< VRadius, TInput, TOutput >Window function for sinc interpolation.

\[ w(x) = \textrm{sinc} ( \frac{x}{m} ) \]

Note: Paper referenced in WindowedSincInterpolateImageFunction gives an incorrect definition of this window function

oCotb::Function::LanczosWindowFunction< TInput, TOutput >Window function for sinc interpolation.

\[ w(x) = \textrm{sinc} ( \frac{x}{m} ) \]

Note: Paper referenced in WindowedSincInterpolateImageFunctionBase gives an incorrect definition of this window function

oCotb::Function::LanczosWindowFunction< TInputInterpolator, TOutputInterpolator >
oCotb::Functor::LandsatTM::LandsatTMIndexBase< TInput, TOutput >Base class for Landsat-TM indices
oCotb::Functor::LandsatTM::LandsatTMIndexBase< TInput, itk::FixedArray< unsigned int, 11 > >
oCLandsatTMLinguisticVariables
oCotb::ogr::LayerLayer of geometric objets
oCotb::ogr::DataSource::layer_iter< Value >Implementation class for Layer iterator
oCotb::LayerValueGenerator< TInputPixelType, TLayerValueType >TODO
oCotb::LayerValueGenerator< itk::RGBAPixel< TInputInternalPixelType >, TLayerValueType >
oCotb::LayerValueGenerator< itk::RGBPixel< TInputInternalPixelType >, TLayerValueType >
oCotb::LayerValueGenerator< itk::VariableLengthVector< TInputInternalPixelType >, TLayerValueType >
oCitk::LBFGSBOptimizerHelperWrapper helper around vnl_lbfgsb
oCLearningFunctionBaseThe LearningFunctionBase is the base class for all the learning strategies. These include error back propagation, bp+momentum, conjugte gradient descent, quick prop. This class specifies how the errors are backpropagated for a layer. They take a LayerBase object as input and compute the input for the layers input weightset
oCitk::Statistics::MeanShiftModeCacheMethod< TMeasurementVector >::LessMeasurementVector
oCitk::Concept::LessThanComparable< T1, T2 >
oCotb::Functor::LevelingFunctor< TInput, TInputMap, TOutput >This functor performs the pixel-wise leveling operation needed in the geodesic morphology decomposition filter. For more details, please refer to the documentation of this filter
oCotb::Functor::LevelingFunctor< TInputImage::PixelType, TInputMaps::PixelType, TOutputImage::PixelType >
oCitk::LevelSetNode< TPixel, VSetDimension >Represent a node in a level set
oCitk::LevelSetTypeDefault< TLevelSet >Level set type information
oCotb::Functor::LHMI< TInput1, TInput2, TOutput >TODO
oCotb::Functor::LHMI< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType >
oCitk::LightObjectLight weight base class for most itk classes