Class Hierarchy

This inheritance list is sorted roughly, but not completely, alphabetically:

[detail level 12345]

►Cboost::addable
Cotb::MetaData::Duration	Represents a duration
Cotb::MetaData::Duration	Represents a duration
Cotb::BandMathXImageFilter< TImage >::adhocStruct
Cotb::Functor::AffineFunctor< TInput, TOutput, TScale >	This functor performs a linear transform of its input
►Cotb::Functor::AlphaBlendingFunctorBase< TInputPixel1, TInputPixel2, TOutputPixel >
Cotb::Functor::AlphaBlendingFunctor< TInputPixel1, TInputPixel2, TOutputPixel >	Implements simple blending
►Cotb::Functor::AlphaBlendingFunctorBase< itk::RGBAPixel< TInputInternalPixel1 >, itk::RGBAPixel< TInputInternalPixel2 >, itk::RGBAPixel< TOutputInternalPixel > >
Cotb::Functor::AlphaBlendingFunctor< itk::RGBAPixel< TInputInternalPixel1 >, itk::RGBAPixel< TInputInternalPixel2 >, itk::RGBAPixel< TOutputInternalPixel > >
Cotb::Functor::AmplitudePhaseToRGBFunctor< TInput1, TInput2, TInput3, TOutput >	Function object to compute a color representation of a radar image
Cotb::Functor::AssociativeSymmetricalSum< TInput1, TInput2, TOutput >	Functor used with the AssociativeSymmetricalSumImageFilter
►Citk::AttributeOpeningLabelMapFilter
Cotb::AttributesMapOpeningLabelMapFilter< TImage >	Attributes opening for AttributesMapLabelObject
Cotb::Functor::AttributesMapLabelObjectAccessor< TLabelObject >	Allows accessing a given field of an AttributesMapLabelObject
Cotb::Functor::AttributesMapMeasurementFunctor< TLabelObject, TMeasurementVector >	This class allows building a measurement vector from an AttributesMapLabelObject
Cotb::Functor::AttributesMapMeasurementFunctor< LabelObjectType, MeasurementVectorType >
Cotb::Functor::AttributesMapMeasurementFunctor< typename TInputLabelMap::LabelObjectType, typename TOutputSampleList::MeasurementVectorType >
Cotb::AzimuthFmRate	This structure is used to manage parameters related to the Azimuth Frequency Modulation rate
Cgrm::BaatzParam
Cotb::Functor::BandStatsAttributesLabelObjectFunctor< TLabelObject, TFeatureImage >	Functor to compute bands statistics attributes
►Cgrm::BaseNode
►Cgrm::Node< BaatzNode >
Cgrm::BaatzNode
►Cgrm::Node< FLSNode >
Cgrm::FLSNode
►Cgrm::Node< SpringNode >
Cgrm::SpringNode
Cgrm::Node< DerivedNode >
Cotb::basic_mdspan< ElementType, Extents, LayoutPolicy >
Cotb::basic_mdspan< double, dynamic_extent, dynamic_extent >
Cotb::Functor::BayesianFunctor< TInputMultiSpectral, TInputMultiSpectralInterp, TInputPanchro, TOutput >	Functor for the bayesian fusion filter. Please refer to BayesianFusionFilter
►Citk::BinaryFunctorImageFilter
CGapFilling::BinaryFunctorImageFilterWithNBands< TInputImage1, TInputImage2, TOutputImage, TFunctor >
Cotb::AssociativeSymmetricalSumImageFilter< TInputImage1, TInputImage2, TOutputImage >	Implements an asymmetric fusion of line detector image filter
Cotb::BinaryFunctorImageFilter< TInputImage1, TInputImage2, TOutputImage, TFunction >	Implements pixel-wise generic operation on two images
Cotb::ImageAndVectorImageOperationFilter< TInputImage, TVectorInputImage, TOutputImage >	Provides simple pixel to pixel operation between Image and VectorImage
Cotb::MultiplyVectorImageFilter< TInputImage1, TInputImage2, TOutputImage >
Cotb::RealAndImaginaryImageToComplexImageFilter< TInputImageRealPart, TInputImageImaginaryPart, TOutputImage >	Computes pixel-wise the complex image of a real and imaginary image
CBinarySpectralAngleFunctor	This functor computes the spectral angle between two pixels
Cotb::Functor::BinarySpectralAngleFunctor< TInput1, TInput2, TOutputValue >
Cotb::Functor::BinarySpectralAngleFunctor< PixelType, PixelType, double >
Cotb::Function::BlackmanWindowFunction< TInput, TOutput >	Window function for sinc interpolation
Cotb::ogr::DataSource::boolean
Cotb::ogr::Layer::boolean	int boolean ::* () const
Cotb::SpectralSensitivityReader::BothAre
Cgrm::BoundingBox
Clp::BoundingBox
Cotb::string_view::build_empty
Cotb::BurstRecord	This structure is used to handle burst records
Cotb::internal::ReprojectTransformationFunctor::ByCopy
Cotb::Wrapper::details::CastImage< TOutputImage, TInputImage >	Helper class (private) which casts and clamps input-image type into output-image type
Cotb::Wrapper::details::CastImage< DoubleVectorImageType, DoubleVectorImageType >
Cotb::Wrapper::details::CastImage< T, T >
Cotb::Wrapper::details::CastImage< TOutputImage, DoubleVectorImageType >
►Citk::CastImageFilter
Cotb::GCPsToRPCSensorModelImageFilter< TImage >	This filter estimates a RPC sensor models from GCPs
Cotb::ImportGeoInformationImageFilter< TImage, TSourceImage >	This filter is a helper class to import metadata from an existing image into a non-georeferenced image
Cotb::PhysicalToRPCSensorModelImageFilter< TImage >	This filter estimates a RPC sensor models from a physical model
Cotb::RasterizeVectorDataFilter< TVectorData, TInputImage, TOutputImage >	Burn geometries from the specified VectorData into raster
Cotb::Functor::CBAMI< TInput1, TInput2, TOutput >
Cotb::Functor::ChangeNoDataFunctor< TInputPixel, TOutputPixel >	Functor used by ChangeNoDataValueFilter
Cotb::string_view::char_iterator
Cotb::Wrapper::ChoiceParameter::Choice
Cotb::ClosePathFunctor< TInput, TOutput >	This filter close the input path, making the last point equal to the first one
Cotb::Functor::MultiScaleConvexOrConcaveDecisionRule_tags::closing_profile_characteristics
CCloudDetectionFunctor	This functor first uses CloudEstimatorFunctor
Cotb::Functor::CloudDetectionFunctor< TInput, TOutputValue >
Cotb::Functor::CloudEstimatorFunctor< TInput, TOutputValue >	Functor to help with the cloud detection
CCoherencyToReciprocalMuellerFunctor	Evaluate the reciprocal Mueller matrix from the reciprocal coherency matrix image
►Citk::Function::ColormapFunction
Cotb::Functor::ReliefColormapFunctor< TScalar, TRGBPixel >	Function object which maps a scalar value into an RGB colormap value for relief representation
Cotb::Functor::ScalarToRainbowRGBPixelFunctor< TScalar, TRGBPixel >	Function object which maps a scalar value into a rainbow RGB pixel value
►Citk::Command
Cotb::CommandProgressUpdate< TFilter >	TODO
Cotb::NeighborhoodMajorityVotingImageFilter< TInputImage, TOutputImage, TKernel >::CompareHistoFequencies
Cotb::Function::ComplexToIntensity< TInput, TOutput >
Cotb::Functor::ComplexToVector< TInput, TOutput >
Cotb::Functor::ComplexToVector< itk::VariableLengthVector< TInput >, TOutput >
Cotb::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
Cotb::Functor::ConcatenateScalarValueFunctor< TInput, TOutput >	TODO
Cotb::Functor::LevelingFunctor_tags::concave_pixel
Cotb::ConfigurationManager	Retrieve configuration values from env var or default values
CConnectedComponentMuParserFunctor	Functor used as input to itk connected component segmentation module
Cotb::Functor::ConnectedComponentMuParserFunctor< TInput >
Cotb::Functor::ConnectedLabelFunctor< TInput >
Cotb::Wrapper::InputImageParameter::Connector
Cotb::ObjectList< TObject >::ConstIterator	ConstIterator of the object list
Cotb::internals::ConstTag
Clp::ContourOperations
Cotb::ConvertPixelBuffer< InputPixelType, OutputPixelType, OutputConvertTraits >	Class to convert blocks of data from one type to another
Cotb::Functor::ConvertTypeFunctor< TInputPixelType, TOutputPixelType >
Cotb::Functor::ConvertTypeFunctor< typename TInputImage::PixelType, typename TOutputImage::PixelType >
Cotb::Functor::LevelingFunctor_tags::convex_pixel
Cotb::CoordinateConversionRecord	This structure contains coefficients to convert between coordinates types, e.g. from ground range to slant range
Cotb::CoordinateTransformation	This class is a wrapper around OGRCoordinateTransformation
Cotb::CorrectPolygonFunctor< TPolygon >	This filter simplify and close the input polygon, making the last point equal to the first one
Cotb::Function::CosineWindowFunction< TInput, TOutput >
Cotb::Count< TPointSet, TRadiusType, TIndexType >	Compute the density of a neighborhood centerred in a pixel
Cotb::ogr::internal::CppToOGRConverter_trait< T >	Trait class for converting C++ types into OGR field setter compatible types
Cotb::ogr::internal::CppToOGRConverter_trait< std::string >	Specialisation for C++ std::string
Cotb::ogr::internal::CppToOGRConverter_trait< T[N]>	Specialisation for C static arrays
Cotb::OGRExtendedFilenameToOptions::CreationOptionType
Cotb::Functor::CrossCorrelation< TInput1, TInput2, TOutput >	Functor to compute the cross correlation
Cotb::CumulantsForEdgeworth< TInput >	Helper class for KullbackLeiblerDistanceImageFilter. Please refer to KullbackLeiblerDistanceImageFilter
Cotb::CumulantsForEdgeworth< ROIInputType1 >
Cotb::CumulantsForEdgeworth< ROIInputType2 >
Cotb::CumulantsForEdgeworthProfile< TInput >	Helper class for KullbackLeiblerProfileImageFilter. Please refer to KullbackLeibleProfileImageFilter
Cotb::Functor::CzihoSOMLearningBehaviorFunctor	Beta behavior over SOM training phase
Cotb::Functor::CzihoSOMNeighborhoodBehaviorFunctor	Neighborhood size behavior over SOM training phase
►Citk::DataObject
►Cotb::ObjectList< TImage >
Cotb::ImageList< TImage >	This class represent a list of images
►Cotb::ObjectList< SamplingRateCalculator >
Cotb::SamplingRateCalculatorList	This class is a list of sampling rate calculators
Cotb::AeronetData	This class is a data structure designed to store Aeronet data extracted from a aeronet file
Cotb::AtmosphericCorrectionParameters	This class contains all atmospheric correction parameters
Cotb::AtmosphericEffects< TSpectralResponse, TRSR >	This class applies atmospheric effects, computed from otbAtmosphericCorrectionParametersTo6SRadiativeTerms to an input spectrum (otbSpectralResponse) using the otbSurfaceReflectanceToReflectanceFilter
Cotb::AtmosphericRadiativeTerms	This class is a vector of AtmosphericRadiativeTermsSingleChannel, it contains all atmospheric radiative terms for each studied channel
Cotb::AtmosphericRadiativeTermsSingleChannel	This class contains all atmospheric radiative terms for one channel
Cotb::DecisionTree< AttributeValueType, LabelType >	Models a decision tree
Cotb::FilterFunctionValues	This class contains the values of the filter function for the processed spectral band
Cotb::FuzzyVariable< TLabel, TPrecision >	Class to represent a fuzzy N-valued variable
Cotb::GeometriesSet	Common ITK type to manipulate any set of geometries: a otb::ogr::DataSource, or a otb::ogr::Layer
Cotb::ImageMetadataCorrectionParameters	This class contains all atmospheric correction parameters
Cotb::Landmark< TPoint, TPointData, TLandmarkData >	This class represent point and point data binary matching
Cotb::LeafParameters	Data class containing Leaf Parameters
Cotb::MassOfBelief< TLabel, TMass >	This class represent a mass of belief function
Cotb::ObjectList< TObject >	This class is a generic all-purpose wrapping around an std::vector<itk::SmartPointer<ObjectType> >
Cotb::PolarimetricData	This class allows determining the type of architecture we get
Cotb::ProSailParameters	This class implements the ProSailParameters lib
Cotb::ReduceSpectralResponse< TSpectralResponse, TRSR >	This class computes the reduced spectral response of each band of a sensor
Cotb::ReduceSpectralResponseClassifierRAndNIR< TReduceSpectralResponse, TFunction >	This class represents a hierarchy of vector data
Cotb::SatelliteRSR< TPrecision, TValuePrecision >	This class represents a hierarchy of vector data
Cotb::SpectralResponse< TPrecision, TValuePrecision >	This class represents the spectral response of an object (or a satellite band)
Cotb::VectorData< TPrecision, VDimension, TValuePrecision >	This class represents a hierarchy of vector data
Cotb::VectorDataProperties< TVectorData >	Compute public properties of the vectordata
Cotb::WavelengthSpectralBands	This class contains the values of the filter functions
Cotb::ogr::DataSource	Collection of geometric objects
CDataObjectListInterface	This non template class is an interface that wrap ObjectList
Cotb::DataSpec	This struct contains the specific absorption coefficients of each constituent and the refractive index of leaf materia
Cotb::DataNode< TPrecision, VDimension, TValuePrecision >::DataType
►Cdecltypeinternals::is_array_fstd::declval
Cotb::mpl::is_array< T >
►Citk::DefaultConvertPixelTraits
Cotb::DefaultConvertPixelTraits< PixelType >
Cotb::DefaultConvertPixelTraits<::std::complex< T > >
►Cotb::DEMObserverInterface	Observer design pattern to keep track of DEM configuration changes
Cotb::GDALRPCTransformer	This class is a wrapper around GDALCreateRPCTransformer and GDALRPCTransform
►Cotb::DEMSubjectInterface	Observer design pattern to keep track of DEM configuration changes
Cotb::DEMHandler	Single access point for DEM data retrieval
Cotb::DimapData	Struct containing metadata parsed from a Dimap product
Cotb::DimapMetadataHelper	Helper class to read dimap data from various sources (Dimap v1, dimap v2, Ossim geom file) and various sensors (PHR, SPOT, ...) and store them in a DimapData struct
►Citk::Statistics::DistanceMetric
Cotb::GeographicalDistance< TVector >	Compute the metric distance between two geographical points
Cotb::MetaData::details::dividable< T, R >
►Cotb::MetaData::details::dividable< Duration, double >
Cotb::MetaData::Duration	Represents a duration
Cotb::DopplerCentroid	This structure is used to handle Doppler centroid estimates
Cotb::Functor::DotProductFunctor< TInput, TOutput >	Computes the dot product against a specific vector
CGapFilling::doy_multi_year
Cotb::ogr::Drivers
Cotb::Wrapper::ElevationParametersHandler	This 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
Cotb::ogr::DataSource::layer_iter< Value >::enabler
Cotb::ogr::Layer::feature_iter< Value >::enabler
Cotb::Functor::EnvelopeSavitzkyGolayInterpolationFunctor< Radius, TSeries, TDates, TWeight >
Cotb::Ephemeris	This structure is used to handle Ephemeris information
►Cboost::equality_comparable
Cotb::MetaData::Duration	Represents a duration
Cotb::MetaData::TimePoint	Represents a point in Time
►Citk::Statistics::EuclideanDistanceMetric
►Cotb::Statistics::EuclideanDistanceMetricWithMissingValuePow2< TVector >	Euclidean comparison distance function facing missing value. The square root is not performed in this class
Cotb::Statistics::EuclideanDistanceMetricWithMissingValue< TVector >	Euclidean distance function facing missing value
Cotb::Statistics::FlexibleDistanceWithMissingValue< TVector >	Non-Euclidean distance function facing missing value
►Citk::EventObject
Cotb::Wrapper::AddProcessToWatchEvent	This class implements an event storing a pointer to itk::ProcessObject and a string describing the process
►Citk::ExceptionObject
Cotb::AeronetFileReaderException	Base exception class for Aeronet problems during reading
Cotb::ApplicationException	Exception for runtime errors in OTB Applications
Cotb::ImageFileReaderException	Base exception class for IO conflicts
Cotb::ImageSeriesFileReaderException
Cotb::MissingMetadataException	Exception to be used when metadata parsing fails
Cotb::VectorDataFileReaderException	Base exception class for IO conflicts
Cotb::VectorDataFileWriterException
Cotb::extents< StaticExtents >
►CF
Cotb::NumberOfOutputBandsDecorator< F >	This struct allows forwarding the operator of template parameter, while adding number of output components service
►Cstd::false_type
Cotb::IsNeighborhood< T >	Struct testing if T is a neighborhood
Cotb::ogr::Feature	Geometric object with descriptive fields
Cotb::Wrapper::TrainVectorBase< TInputValue, TOutputValue >::FeaturesInfo
Cotb::OGRLayerStreamStitchingFilter< TInputImage >::FeatureStruct
Cotb::ogr::Field	Encapsulation of OGRField Instances of Field are expected to be built from an existing Feature with which they'll share their owning OGRFeature
Cotb::FieldCopyTransformation
Cotb::ogr::FieldDefn	Encapsulation of OGRFieldDefn: field definition
►CFieldTransformationPolicy
Cotb::TransformationFunctorDispatcher< TransformationFunctor, OGRGeometry, FieldTransformationPolicy >
Cotb::TransformationFunctorDispatcher< TransformationFunctor, ogr::Layer, FieldTransformationPolicy >
►CFunctorFilterSuperclassHelper::FilterType
►Cotb::FunctorImageFilter< Functor::BayesianFunctor< TInputMultiSpectralImage::PixelType, TInputMultiSpectralInterpImage::PixelType, TInputPanchroImage::PixelType, TOutputImage::PixelType > >
Cotb::BayesianFusionFilter< TInputMultiSpectralImage, TInputMultiSpectralInterpImage, TInputPanchroImage, TOutputImage >	Bayesian fusion filter. Contribution of Julien Radoux
►CFunctorFilterSuperclassHelper::FilterType
Cotb::FunctorImageFilter< TFunction, TNameMap >	A generic functor filter templated by its functor
►Cotb::FilterWatcherBase	This class is an abstract class Provides an interface to progress task mechanic
Cotb::StandardFilterWatcher	This class shows the percentage progress execution of the pipeline filtering process
Cotb::StandardOneLineFilterWatcher< PrintCallbackType >	This class shows the percentage progress execution of the pipeline filtering process
Cgrm::FLSParam
►Citk::FunctionBase
►Cotb::PathFunction< TInputPath, double >
►Cotb::GeometricMomentPathFunction< TInputPath, double, double >
►Cotb::RealMomentPathFunction< TInputPath, double, double >
Cotb::FlusserPathFunction< TInputPath, TOutput, TPrecision >	Calculate the Flusser's invariant parameters
Cotb::HuPathFunction< TInputPath, TOutput, TPrecision >	Calculate the Hu's invariant parameter
Cotb::RealMomentPathFunction< TInputPath, TOutput, TPrecision >	Virtual class for the Real moments for a path
Cotb::CompacityPathFunction< TInputPath, TOutput >	Calculate the compacity of a path. The formula of the compacity is :
Cotb::OrientationPathFunction< TInputPath, TOutput >	Calculate the orientation angle of a path defined by 2 points. The result value is in radian
Cotb::DataNodeFunctionBase< TDataNode, TOutput >	Base class for DataNode functions
Cotb::MetaImageFunction< TOutputPrecision, TCoordRep >	Concatenate results from multiple ImageFunction
►Cotb::PathFunction< TInputPath, TOutput >	Evaluates a function of an image over a specific path
►Cotb::GeometricMomentPathFunction< TInputPath, std::complex< double >, double >
Cotb::ComplexMomentPathFunction< TInputPath, TOutput, TPrecision >	Calculate the complex moment value over a path
Cotb::GeometricMomentPathFunction< TInputPath, TOutput, TPrecision >	Virtual class for the Geometric moments for an path function
Cotb::FunctorFilterSuperclassHelper< T, TNameMap >	Struct allowing to derive the superclass prototype for the FunctorImageFilter class
Cotb::FunctorFilterSuperclassHelper< R(*)(T...), TNameMap >	Partial specialisation for R(*)(T...)
Cotb::FunctorFilterSuperclassHelper< R(C::*)(T...) const, TNameMap >	Partial specialisation for R(C::*)(T...) const
Cotb::FunctorFilterSuperclassHelper< R(C::*)(T...), TNameMap >	Partial specialisation for R(C::*)(T...)
Cotb::FunctorFilterSuperclassHelper< void(*)(R &, T...), TNameMap >	Partial specialisation for void(*)(R &,T...)
Cotb::FunctorFilterSuperclassHelper< void(C::*)(R &, T...) const, TNameMap >	Partial specialisation for void(C::*)(R&,T...) const
Cotb::FunctorFilterSuperclassHelper< void(C::*)(R &, T...), TNameMap >	Partial specialisation for void(C::*)(R&,T...)
Cotb::functor_filter_details::FunctorFilterSuperclassHelperImpl< R, TNameMap, T >
Cotb::SimpleRcsPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >::FusionFunctor
Cotb::LmvmPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >::FusionFunctor1
Cotb::LmvmPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >::FusionFunctor2
Cotb::OGRLayerStreamStitchingFilter< TInputImage >::FusionStruct
Cotb::FuzzyDescriptorsModelManager	Read a xml file where are stored several statistics
Cotb::Function::GaussianWindowFunction< TInput, TOutput >	Gaussian interpolation windowing function
Cotb::GCP	This GCP class is used to manage the GCP parameters in OTB
Cotb::Projection::GCPParam	This structure handles the list of the GCP parameters
Cotb::GCPTime	This structure contains the azimuth and range times associated with a gcp
Cotb::GDALDriverManagerWrapper	Provide an unique instance of a GDALDataSet
Cotb::details::generic_layout< LayoutPolicy >
Cotb::ogr::internal::GeometryDeleter
Cotb::functor_filter_details::GetProxy< T >
Cotb::functor_filter_details::GetProxy< itk::ConstNeighborhoodIterator< T > >
Cotb::functor_filter_details::GetProxy< itk::ImageRegionConstIterator< T > >
Cotb::NCCRegistrationFunction< TFixedImage, TMovingImage, TDisplacementField >::GlobalDataStruct
Cgrm::Graph< TNode >
Cgrm::Graph< NodeType >
Cgrm::GraphOperations< TSegmenter >
Cgrm::GraphToOtbImage< TGraph >
CGroup
Cotb::Function::HammingWindowFunction< TInput, TOutput >	Window function for sinc interpolation
Cotb::Functor::HessianDeterminant< TInput, TOutput >	This functor computes the determinant of symmetric 2*2 matrix
Cotb::Functor::HessianToScalar< TInput, TOutput >
Cotb::polarimetry_tags::hh
Cotb::Functor::HillShadeModulationFunctor< TInput1, TInput2, TOutput >	Modulate an image with hill shading
Cotb::Functor::HillShadingFunctor< TNeighIter, TInputImage, TOutput >	Unary neighborhood functor to compute the lambertian of a surface
►Citk::HistogramAlgorithmBase
Cotb::HistogramStatisticsFunction< TInputHistogram, TOutput >	Computes parameters for a histogram
Cotb::NeighborhoodMajorityVotingImageFilter< TInputImage, TOutputImage, TKernel >::HistoSummary
Cotb::Functor::HorizontalSobelOperator< TInput, TOutput >	Performs the calculation of horizontal Sobel derivation
Cotb::Functor::HSVToRGBFunctor< TRGBPixel >	Function object to convert HSV value to RGB
Cotb::Functor::HSVToRGBFunctor< RGBPixelType >
Cotb::polarimetry_tags::hv
Cotb::polarimetry_tags::hv_or_vh
►Cmup::ICallback
Cotb::bands
Cotb::cat
Cotb::corr
Cotb::dotpr
Cotb::maj
Cotb::mean
Cotb::median
Cotb::ndvi
Cotb::vabs
Cotb::vacos
Cotb::var
Cotb::vasin
Cotb::vatan
Cotb::vcos
Cotb::vcosh
Cotb::vect2scal
Cotb::vexp
Cotb::vlog
Cotb::vlog10
Cotb::vmax
Cotb::vmin
Cotb::vnorm
Cotb::vsin
Cotb::vsinh
Cotb::vsqrt
Cotb::vtan
Cotb::vtanh
CGapFilling::IdentityGapFillingFunctor< PixelType >
►Citk::Image
Cotb::Image< TPixel, VImageDimension >	Creation of an "otb" image which contains metadata
►Citk::ImageAdaptor
Cotb::ShiftScaleImageAdaptor< TImage, TOutputPixelType >	Presents an image as being composed of the shift scale operation of its pixels
Cotb::VectorImageToASImageAdaptor< TImage >	Presents an image of pixel type Vector as being and image of FixelArray<unsigned short, 3> type
►Citk::ImageAndPathToImageFilter
Cotb::DrawPathFilter< TInputImage, TInputPath, TOutputImage >	This class can be used to draw a single path on an image
Cotb::Functor::ImageAndVectorImageOperationFunctor< TInput, TVectorInput, TOutput >
►Cotb::ImageCommons
►Cotb::VectorImage< TNeuron::ComponentType, 2 >
Cotb::SOMMap< TNeuron, TDistance, VMapDimension >	This class represent a Self Organizing Map
Cotb::Image< TPixel, VImageDimension >	Creation of an "otb" image which contains metadata
Cotb::VectorImage< TPixel, VImageDimension >	Creation of an "otb" vector image which contains metadata
Cotb::ImageToOSMVectorDataGenerator< TImage >::ImageExtentType
CImageFileWriterException	Base exception class for IO problems during writing
►Citk::ImageFunction
Cotb::BinaryImageDensityFunction< TInputImage, TCoordRep >	Calculate the density pixel of in the neighborhood of a pixel
Cotb::ComplexMomentsImageFunction< TInputImage, TCoordRep >	Calculate the complex moment values in the specified neighborhood
Cotb::FlusserMomentsImageFunction< TInputImage, TCoordRep >	Calculate the Flusser's invariant parameters
Cotb::FourierMellinDescriptorsImageFunction< TInputImage, TCoordRep >	Calculate the Fourier-Mellin descriptors in the specified neighborhood
Cotb::GroundSpacingImageFunction< TInputImage, TCoordRep >	Calculate the approximate ground spacing in X and Y directions
Cotb::HaralickTexturesImageFunction< TInputImage, TCoordRep >	Compute the 8 Haralick texture indices on the neighborhood of the point
Cotb::HistogramOfOrientedGradientCovariantImageFunction< TInputImage, TOutputPrecision, TCoordRep >	Calculate the centered HOG features
Cotb::HuMomentsImageFunction< TInputImage, TCoordRep >	Calculate the Hu's invariant parameters
Cotb::ImageFunctionAdaptor< TInternalImageFunctionType, TOutputPrecision >	Adapt the output of the internal image function to be a itk::VariableLengthVector
Cotb::LocalHistogramImageFunction< TInputImage, TCoordRep >	Calculate a local histogram over a specified circular neighborhood
Cotb::RadiometricMomentsImageFunction< TInputImage, TCoordRep >	Calculate the radiometric moments
Cotb::RealMomentsImageFunction< TInputImage, TCoordRep >	Calculate the moment values in the specified neighborhood
Cotb::SarBrightnessFunction< TInputImage, TCoordRep >	Calculate the backscatter for the given pixel
Cotb::SarParametricMapFunction< TInputImage, TCoordRep >	Evaluates a parametric bidimensionnal polynomial model from a PointSet
Cotb::SarRadiometricCalibrationFunction< TInputImage, TCoordRep >	Calculate the backscatter for the given pixel
Cotb::TextureImageFunction< TInputImage, TFunctor, TCoordRep >	Calculate a texture over an image
►Cotb::ImageMetadataBase	Metadata hybrid dictionary
Cotb::ImageMetadata	Generic class containing image metadata used in OTB
Cotb::ogr::ImageReference< TPrecision >
Cotb::ogr::ImageReference< double >
►Citk::ImageRegionConstIterator
Cotb::Meanshift::FastImageRegionConstIterator< TImage >
►Cotb::SubsampledImageRegionConstIterator< TImage >	Regular subsample iterator over an image
Cotb::SubsampledImageRegionIterator< TImage >	Regular subsample iterator over an image
►Citk::ImageRegionSplitter
Cotb::ImageRegionAdaptativeSplitter< VImageDimension >
Cotb::ImageRegionNonUniformMultidimensionalSplitter< VImageDimension >	Divide a region into several pieces
Cotb::ImageRegionSquareTileSplitter< VImageDimension >	Divide a region into several pieces
Cotb::ImageRegionTileMapSplitter< VImageDimension >	Divide a region into several pieces
Cotb::StreamingShrinkImageRegionSplitter
►Citk::ImageSource
►Cotb::ImageListToImageFilter< TImageList::ImageType, TVectorImage >
Cotb::ImageListToVectorImageFilter< TImageList, TVectorImage >	Converts an ImageList to a VectorImage
►Cotb::ImageListToImageFilter< TImageList::ImageType, TImage >
Cotb::WaveletsBandsListToWaveletsSynopsisImageFilter< TImageList, TImage >	Converts a list of wavelets bands to the traditional multi-resolution wavelets view
►Cotb::ImageListToImageFilter< TInputImageType, TInputImageType >
Cotb::ImageListToSingleImageFilter< TInputImageType >	This class aims at converting a image list to one (scalar or vector) image
►Cotb::SOM< TListSample, TMap, Functor::CzihoSOMLearningBehaviorFunctor, Functor::CzihoSOMNeighborhoodBehaviorFunctor >
►Cotb::PeriodicSOM< TListSample, TMap, Functor::CzihoSOMLearningBehaviorFunctor, Functor::CzihoSOMNeighborhoodBehaviorFunctor >
Cotb::SOMWithMissingValue< TListSample, TMap, TSOMLearningBehaviorFunctor, TSOMNeighborhoodBehaviorFunctor >	This class implements SOM training with missing value
Cotb::PeriodicSOM< TListSample, TMap, TSOMLearningBehaviorFunctor, TSOMNeighborhoodBehaviorFunctor >	This class is responsible for the learning of a self organizing map when considered as a torus
►Cotb::VariadicInputsImageFilter< TOuptut, TInputs... >
Cotb::VariadicNamedInputsImageFilter< TOuptut, TInputNameMap, TInputs >	Adds tagged versions for Get/SetInput to otb::VariadicInputsImageFilter
Cotb::DEMToImageGenerator< TDEMImage >	Class to generate an image from DEM data
Cotb::ImageFileReader< TOutputImage, ConvertPixelTraits >	Reads image data
►Cotb::ImageListToImageFilter< TInputImage, TOutputImage >	Base class for all the filters taking an images list as input to produce an image
Cotb::ProfileDerivativeToMultiScaleCharacteristicsFilter< TInputImage, TOutputImage, TLabeledImage >	This filter extracts the maximum derivative value of the input profile
Cotb::WaveletPacketTransform< TInputImage, TOutputImage, TFilter, Wavelet::INVERSE, FullyDecomposedWaveletPacketCost< TInputImage > >
Cotb::WaveletTransform< TInputImage, TOutputImage, TFilter, Wavelet::INVERSE >
Cotb::ImageSimulationMethod< TInputVectorData, TSpatialisation, TSimulationStep1, TSimulationStep2, TFTM, TOutputImage >	Image simulation method
Cotb::ImportImageFilter< TOutputImageType >	Import data from a standard C array into an Image Type
Cotb::ImportVectorImageFilter< TOutputImageType >	Import data from a standard C array into an Image Type
Cotb::OGRDataSourceToLabelImageFilter< TOutputImage >	Burn geometries from the specified VectorData into raster
Cotb::SOM< TListSample, TMap, TSOMLearningBehaviorFunctor, TSOMNeighborhoodBehaviorFunctor >	This class is responsible for the learning of a self organizing map from a set of vector represented by the input image (each vector is a pixel of the image)
Cotb::StereorectificationDisplacementFieldSource< TInputImage, TOutputImage >	Compute the deformation fields for stereo-rectification
Cotb::VariadicInputsImageFilter< TOuptut, TInputs >	Base class for image filter with variadic inputs
Cotb::VectorDataToLabelImageFilter< TVectorData, TOutputImage >	Burn geometries from the specified VectorData into raster
Cotb::WaveletPacketTransform< TInputImage, TOutputImage, TFilter, TDirectionOfTransformation, TCost >	Wavelet packet transformation framework
Cotb::WaveletTransform< TInputImage, TOutputImage, TFilter, TDirectionOfTransformation >	Wavelet transformation framework
►Citk::ImageToImageFilter
►Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::LHMI< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::LHMIChangeDetector< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of the cumulant-based approximation to mutual information
►Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::KullbackLeiblerSupervizedDistance< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TInputROIImage, TOutputImage::PixelType > >
Cotb::KullbackLeiblerSupervizedDistanceImageFilter< TInputImage1, TInputImage2, TInputROIImage, TOutputImage >	Implements KullbackLeibler distance over Edgeworth approximation, between a Neighborhood and a predefined Region of Interest
►Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::KullbackLeiblerDistance< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::KullbackLeiblerDistanceImageFilter< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of KullbackLeibler distance over Edgeworth approximation
►Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::MeanDifference< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::MeanDifferenceImageFilter< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of mean difference
►Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::MeanRatio< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::MeanRatioImageFilter< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of mean ratio
►Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::CrossCorrelation< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::CorrelationChangeDetector< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of crosscorrelation
►Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::CBAMI< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::CBAMIChangeDetector< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of the cumulant-based approximation to mutual information
►Cotb::BinaryFunctorNeighborhoodJoinHistogramImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::JoinHistogramMI< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::JoinHistogramMIImageFilter< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of mutual information using a join histogram
►Cotb::ExtractROIBase< VectorImage< TInputPixelType, 2 >, VectorImage< TOutputPixelType, 2 > >
Cotb::MultiChannelExtractROI< TInputPixelType, TOutputPixelType >	Extract a spatial or spectral subset of a multi-channel image
►Cotb::ExtractROIBase< Image< TInputPixel, 2 >, Image< TOutputPixel, 2 > >
Cotb::ExtractROI< TInputPixel, TOutputPixel >	Extract a subset of a mono-channel image
►Cotb::ExtractROIBase< VectorImage< TInputPixelType, 2 >, Image< TOutputPixelType, 2 > >
Cotb::MultiToMonoChannelExtractROI< TInputPixelType, TOutputPixelType >	Extract a mono channel part of a multi-channel image
►Cotb::ImageToModulusAndDirectionImageFilter< TInputImage, TOutputImage, TOutputImage >
►Cotb::LineDetectorImageFilterBase< TInputImage, TOutputImage, TOutputImage, itk::LinearInterpolateImageFunction< TInputImage > >
Cotb::AsymmetricFusionOfLineDetectorImageFilter< TInputImage, TOutputImage, TOutputImageDirection, TInterpolator >
Cotb::LineCorrelationDetectorImageFilter< TInputImage, TOutputImage, TOutputImageDirection, TInterpolator >	To be documented
Cotb::LineRatioDetectorImageFilter< TInputImage, TOutputImage, TOutputImageDirection, TInterpolator >	Application of detection of linear features based on the ratio of local means
Cotb::LineDetectorImageFilterBase< TInputImage, TOutputImage, TOutputImageDirection, TInterpolator >	Base class for line detector filters
Cotb::TouziEdgeDetectorImageFilter< TInputImage, TOutputImage, TOutputImageDirection >	Application of a filter of detection of contours
►Cotb::LabelizeImageFilterBase< TInputImage, TOutputImage, itk::ConnectedThresholdImageFilter< TInputImage, TOutputImage > >
Cotb::LabelizeConnectedThresholdImageFilter< TInputImage, TOutputImage >	TODO
►Cotb::LabelizeImageFilterBase< TInputImage, TOutputImage, itk::NeighborhoodConnectedImageFilter< TInputImage, TOutputImage > >
Cotb::LabelizeNeighborhoodConnectedImageFilter< TInputImage, TOutputImage >	Labels pixels that are connected to a seed and lie within a neighborhood
►Cotb::LabelizeImageFilterBase< TInputImage, TOutputImage, itk::ConfidenceConnectedImageFilter< TInputImage, TOutputImage > >
Cotb::LabelizeConfidenceConnectedImageFilter< TInputImage, TOutputImage >	Labels pixels with similar statistics using connectivity
►Cotb::PersistentImageFilter< TInputImage, TInputImage >
►Cotb::PersistentSamplingFilterBase< TInputImage, TMaskImage >
Cotb::PersistentOGRDataToClassStatisticsFilter< TInputImage, TMaskImage >	Persistent filter to compute class statistics based on vectors
Cotb::PersistentOGRDataToSamplePositionFilter< TInputImage, TMaskImage, TSampler >	Persistent filter to extract sample position from an image
Cotb::PersistentCompareImageFilter< TInputImage >	Compute mean squared error, mean absolute error and PSNR of two imagee using the output requested region
Cotb::PersistentHistogramVectorImageFilter< TInputImage >	Compute the histogram of a large image using streaming
Cotb::PersistentInnerProductVectorImageFilter< TInputImage >	Compute the inner product of a large image using streaming
Cotb::PersistentMatrixTransposeMatrixImageFilter< TInputImage, TInputImage2 >	Compute
Cotb::PersistentMinMaxImageFilter< TInputImage >	Compute min. max of an image using the output requested region
Cotb::PersistentMinMaxVectorImageFilter< TInputImage >	Compute min. max of a large image using streaming
►Cotb::PersistentSamplingFilterBase< TInputImage, TMaskImage >	Base class for persistent filter doing sampling tasks
Cotb::PersistentImageSampleExtractorFilter< TInputImage >	Persistent filter to extract sample values from an image
Cotb::PersistentShrinkImageFilter< TInputImage, TOutputImage >
Cotb::PersistentStatisticsImageFilter< TInputImage >	Compute min. max, variance and mean of an image using the output requested region
Cotb::PersistentStreamingStatisticsVectorImageFilter< TInputImage, TPrecision >	Compute covariance & correlation of a large image using streaming
Cotb::PersistentVectorImageToMatrixFilter< TInputImage >	Compute covariance & correlation of a large image using streaming
Cotb::PersistentVectorizationImageFilter< TInputImage, TOutputPath >	Perform vectorization in a persistent way
►Cotb::PersistentImageFilter< TInputLabelImage, TInputLabelImage >
Cotb::PersistentLabelImageSmallRegionMergingFilter< TInputLabelImage >
►Cotb::PersistentImageFilter< TImage, TImage >
Cotb::PersistentImageToOGRDataFilter< TImage >	Perform vectorization in a persistent way
Cotb::PersistentImageToOGRLayerFilter< TImage >	Perform vectorization in a persistent way
Cotb::PersistentImageToVectorDataFilter< TImage, TOutputVectorData >	Perform vectorization in a persistent way
►Cotb::PersistentImageFilter< TInputVectorImage, TInputVectorImage >
Cotb::PersistentStreamingStatisticsMapFromLabelImageFilter< TInputVectorImage, TLabelImage >	Computes mean radiometric value for each label of a label image, based on a support VectorImage
►Cotb::StreamingMosaicFilterBase< TInputImage, TOutputImage, double >
►Cotb::StreamingMosaicFilterWithBlendingBase< TInputImage, TOutputImage, TDistanceImage, double >
►Cotb::StreamingFeatherMosaicFilter< TInputImage, TOutputImage, TDistanceImage, TInternalValueType >	Computes the mosaic of an input images set using feathering technique. The output is a nice seamless mosaic
Cotb::StreamingMultibandFeatherMosaicFilter< TInputImage, TOutputImage, TDistanceImage >	Computes a nice seamless mosaic using multiband strategy
Cotb::StreamingLargeFeatherMosaicFilter< TInputImage, TOutputImage, TDistanceImage, TInternalValueType >	Computes the mosaic of an input images set using feathering technique. The output is a nice seamless mosaic. Images are all added-weighted on all overlapping areas. This could give nice results for perfectly aligned images but can also cause blur on misaligned overlaps
Cotb::StreamingMosaicFilterWithBlendingBase< TInputImage, TOutputImage, TDistanceImage, TInternalValueType >	Base class for mosaic filters with blending
►Cotb::StreamingMosaicFilterBase< TInputImage, TOutputImage, TPrecisionType >
Cotb::PersistentMosaicFilter< TInputImage, TOutputImage, TPrecisionType >	This filter is the base class for all mosaic filter persisting data through multiple update. For instance, a filter computing global statistics on an mosaic with streaming capabilities will have to keep the temporary results for each streamed piece of the image in order to synthesize the global statistics at the end. This filter is an itk::ImageToImageFilter, providing two additional methods. The first one, Synthetize(), allows the user to synthesize temporary data produced by the multiple updates on different pieces of the image to the global result. The second one, Reset(), allows the user to reset the temporary data for a new input image for instance
►Cotb::StreamingMosaicFilterBase< TInputImage, TInputImage, double >
►Cotb::PersistentMosaicFilter< TInputImage, TInputImage, double >
Cotb::PersistentStatisticsMosaicFilter< TInputImage, TOutputImage, TInternalValueType >	Computes the statistics of a mosaic from an input images set. The output pixel value is equal to the number of overlaps
Cotb::StreamingSimpleMosaicFilter< TInputImage, TOutputImage, TInternalValueType >	Computes the mosaic of an input images set. The output pixel value is equal to the first input pixel of the stack which is different from the Superclass::GetNoDataInputPixel()
►Cotb::UnaryFunctorNeighborhoodImageFilter< TInputImage, TOutputImage, Functor::ComputeNeighborhoodContributionFunctor< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType > >
Cotb::SurfaceAdjacencyEffectCorrectionSchemeFilter< TInputImage, TOutputImage >	Correct the scheme taking care of the surrounding pixels
►Cotb::UnaryFunctorNeighborhoodImageFilter< TInputImage1, TOutputImage, Functor::MeanFilterFunctor< itk::ConstNeighborhoodIterator< TInputImage1 >, TOutputImage::PixelType > >
Cotb::MeanFilter< TInputImage1, TOutputImage >
►Cotb::UnaryFunctorNeighborhoodImageFilter< TInputImage, TOutputImage, Functor::LabelToBoundaryFunctor< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType > >
Cotb::LabelToBoundaryImageFilter< TInputImage, TOutputImage >	Filter to extract boundaries of a label image
►Cotb::UnaryFunctorNeighborhoodImageFilter< TInputImage, TOutputImage, Functor::HillShadingFunctor< itk::ConstNeighborhoodIterator< TInputImage >, TInputImage, TOutputImage::PixelType > >
Cotb::HillShadingFilter< TInputImage, TOutputImage >	Filter to compute the lambertian of a surface given as an image
►Cotb::UnaryFunctorNeighborhoodImageFilter< TInputImage1, TOutputImage, Functor::OutcoreFunctor< itk::ConstNeighborhoodIterator< TInputImage1 >, TOutputImage::PixelType > >
Cotb::OutcoreFilter< TInputImage1, TOutputImage >
Cotb::AdhesionCorrectionFilter< TImage, TMask >	This filter eliminates pixels risking adhesion from the input disparity map. To do so it applies the following steps :
Cotb::AngularProjectionBinaryImageFilter< TInputImage, TOutputImage, TPrecision >	Performs
Cotb::AngularProjectionImageFilter< TInputImage, TOutputImage, TAngleArray, TPrecision >	Performs spherical transformation in ND space
Cotb::ApplyGainFilter< TInputImage, TLut, TOutputImage >	Apply gain on the input image with a bilineare interpolation
Cotb::BSplineDecompositionImageFilter< TInputImage, TOutputImage >	This class is an evolution of the itk::BSplineDecompositionImageFilter to handle huge images with this interpolator. For more documentation, please refer to the original class
Cotb::BandMathXImageFilter< TImage >	Performs mathematical operations on the input images according to the formula specified by the user
Cotb::BijectionCoherencyFilter< TDisparityImage, TOutputImage >	Left-right coherency filter for disparity maps
Cotb::BinaryFunctorNeighborhoodImageFilter< TInputImage1, TInputImage2, TOutputImage, TFunction >	Implements neighborhood-wise generic operation of two images
Cotb::BinaryFunctorNeighborhoodJoinHistogramImageFilter< TInputImage1, TInputImage2, TOutputImage, TFunction >	Implements neighborhood-wise generic operation of two images
Cotb::BinaryImageToDensityImageFilter< TInputImage, TOutputImage, TCountFunction >	This class performs a streaming isotropic shrinking operation without smoothing
Cotb::CLHistogramEqualizationFilter< TInputImage, TOutputImage >	Implement CLAHE algorithm
Cotb::ClampImageFilter< TInputImage, TOutputImage >	Clamp image values to be below, over, or between threshold values
Cotb::ClampVectorImageFilter< TInputImage, TOutputImage >	Set image values to a user-specified value if they are below, above, or between simple threshold values
Cotb::ClosingOpeningMorphologicalFilter< TInputImage, TOutputImage, TKernel >	This filter implements an opening grayscale morphological operation followed by a closing grayscale morphological operation. It tends to simplify image by obliterating details with a lower extent than the structuring element
Cotb::ComputeGainLutFilter< TInputImage, TOutputImage >	Compute the gain for each pixel value from a histogram
Cotb::ComputeHistoFilter< TInputImage, TOutputImage >	Compute local histogram with several parameters
Cotb::ConcatenateVectorImageFilter< TInputImage1, TInputImage2, TOutputImage >	This filter concatenates the vector pixel of the first image with the vector pixel of the second image
Cotb::ConvolutionImageFilter< TInputImage, TOutputImage, TBoundaryCondition, TFilterPrecision >	Applies a convolution filter to a mono channel image
Cotb::DEMCaracteristicsExtractor< TInputImage, TOutputImage >	Calculates the slope, the orientation incidence and exitance radius values for each pixel
Cotb::DSFusionOfClassifiersImageFilter< TInputImage, TOutputImage, TMaskImage >	Performs a fusion of n classification maps using the Dempster Shafer (noted DS) rule of combination
Cotb::DecimateImageFilter< TInputImage, TOutputImage >	Performs a down sampling of an image
Cotb::DisparityMapMedianFilter< TInputImage, TOutputImage, TMask >	Applies a median filter to a monoband disparity map with an associated mask
Cotb::DisparityMapTo3DFilter< TDisparityImage, TOutputImage, TEpipolarGridImage, TMaskImage >	Project an input disparity map into a 3D points
Cotb::DisparityMapToDEMFilter< TDisparityImage, TInputImage, TOutputDEMImage, TEpipolarGridImage, TMaskImage >	Project an input disparity map into a regular DEM
Cotb::DisparityTranslateFilter< TDisparityImage, TGridImage, TSensorImage, TMaskImage >	Translate epipolar disparities into sensor disparities
Cotb::DrawPathListFilter< TInputImage, TInputPath, TOutputImage >	This class can be used to draw a list of path on an image
Cotb::EdgeDensityImageFilter< TInputImage, TOutputImage, TEdgeDetector, TDensityCount >	This composite filter computes the density of the edges around a pixel
Cotb::EdgeDetectorImageFilter< TInputImage, TOutputImage, TEdgeDetection >	This composite filter binaries a edge detection image output. The used edge detection filter is given as template of the class. The class only supports Image
Cotb::EstimateInnerProductPCAImageFilter< TInputImage, TOutputImage >	Applies the Inner product to an vector image. Implement the itk::ImagePCAShapeModelEstimator algorithms in streaming capabilities Use by the InnerProductPCAImageFilter composite filter
►Cotb::ExtractROIBase< TInputImage, TOutputImage >	Base class to extract area of images
Cotb::ImageOfVectorsToMonoChannelExtractROI< TInputImage, TOutputImage >
Cotb::FastICAImageFilter< TInputImage, TOutputImage, TDirectionOfTransformation >	Performs a Independent Component Analysis (ICA)
Cotb::FineRegistrationImageFilter< TInputImage, T0utputCorrelation, TOutputDisplacementField >	Computes a displacement field between two images using a given metric
Cotb::ForwardFourierMellinTransformImageFilter< TPixel, TInterpol, Dimension >	Calculate the Fourier-Mellin transform over an image
Cotb::FrostImageFilter< TInputImage, TOutputImage >	Anti-speckle image filter
Cotb::GammaMAPImageFilter< TInputImage, TOutputImage >	Anti-speckle image filter
Cotb::GenericRSResampleImageFilter< TInputImage, TOutputImage >	This class is a composite filter that allows you to project an input image from any coordinate system to any other one. The coordinate systems can be defined by their projection reference, the keyword list or a meta data dictionary
Cotb::GeodesicMorphologyDecompositionImageFilter< TInputImage, TOutputImage, TStructuringElement >	This class implements a geodesic morphology based image analysis algorithm
Cotb::GridResampleImageFilter< TInputImage, TOutputImage, TInterpolatorPrecision >	Resample input image on a new origin/spacing/size grid
Cotb::HarrisImageFilter< TInputImage, TOutputImage >	This filter performs the computation of the Harris measure as followed
Cotb::ImageClassificationFilter< TInputImage, TOutputImage, TMaskImage >	This filter performs the classification of a VectorImage using a Model
Cotb::ImageDimensionalityReductionFilter< TInputImage, TOutputImage, TMaskImage >
Cotb::ImageToHessianDeterminantImageFilter< TInputImage, TOutputImage, TPrecision >	This class compute the Hessian determinant of each pixel of an input image
Cotb::ImageToLabelMapWithAttributesFilter< TInputImage, TLabeledImage, TLabel, TLabelObject >	Convert a labeled image to a label map with adjacency information and computes feature attributes for each LabelObject
Cotb::ImageToModulusAndDirectionImageFilter< TInputImage, TOutputImage, TOutputImageDirection >	Base class for modulus and direction image filters
Cotb::InnerProductPCAImageFilter< TInputImage, TOutputImage >	Performs a PCA with streaming capabilities
Cotb::KeyPointDensityImageFilter< TInputImage, TOutputImage, TDetector >	This class computes the density of the characteristic points detected in the image
Cotb::KuanImageFilter< TInputImage, TOutputImage >	Anti-speckle image filter
Cotb::LabelImageRegionMergingFilter< TInputLabelImage, TInputSpectralImage, TOutputLabelImage, TOutputClusteredImage >
Cotb::LabelImageRegionPruningFilter< TInputLabelImage, TInputSpectralImage, TOutputLabelImage, TOutputClusteredImage >
Cotb::LabelizeImageFilterBase< TInputImage, TOutputImage, TFilter >	Base class for filter labelizing image region based on segmentation
Cotb::LeeImageFilter< TInputImage, TOutputImage >	Anti-speckle image filter
Cotb::LmvmPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >	This class performs a Local Mean and Variance Matching (LMVM) Pan sharpening operation
Cotb::MDMDNMFImageFilter< TInputImage, TOutputImage >
►Cotb::MNFImageFilter< TInputImage, TOutputImage, TNoiseImageFilter, TDirectionOfTransformation >	Performs a Maximum Noise Fraction analysis of a vector image
Cotb::NAPCAImageFilter< TInputImage, TOutputImage, TNoiseImageFilter, TDirectionOfTransformation >	Performs a Noise Adjusted PCA analysis of a vector image
Cotb::MarkovRandomFieldFilter< TInputImage, TClassifiedImage >	This is the class to use the Markov Random Field framework in OTB
Cotb::MaskMuParserFilter< TInputImage, TOutputImage, TFunction >
Cotb::MatrixImageFilter< TInputImage, TOutputImage, TMatrix >	Apply a matrix multiplication over the channels of an image
Cotb::MaximumAutocorrelationFactorImageFilter< TInputImage, TOutputImage >	This filter implements the Maximum Autocorrelation Factor
Cotb::MeanShiftConnectedComponentSegmentationFilter< TVInputImage, TMaskImage, TLabelImage >	[internal] Helper class to perform connected component segmentation on an input image,
Cotb::MeanShiftSegmentationFilter< TInputImage, TOutputLabelImage, TOutputClusteredImage, TKernel >
Cotb::MeanShiftSmoothingImageFilter< TInputImage, TOutputImage, TKernel, TOutputIterationImage >
Cotb::MorphologicalProfilesSegmentationFilter< TInputImage, TOutputImage, TInternalPrecision, TStructuringElement >	This class implements segmentation by morphological profiles
Cotb::Multi3DMapToDEMFilter< T3DImage, TMaskImage, TOutputDEMImage >	Project N 3D images (long,lat,alti) into a regular DEM in the chosen map projection system
Cotb::MultiDisparityMapTo3DFilter< TDisparityImage, TOutputImage, TMaskImage, TResidueImage >	Project a group of disparity map into 3D points
Cotb::MultivariateAlterationDetectorImageFilter< TInputImage, TOutputImage >	This filter implements the Multivariate Alteration Detector
Cotb::NLMeansFilter< TInputImage, TOutputImage >	This class implements a fast approximated version of NL Means denoising algorithm. This implementation is based on code in scikit module skimage. This fast version of the NL Means algorithm has been described in the following papers :
Cotb::NRIBandImagesToOneNComplexBandsImage< TInputImage, TOutputImage >
Cotb::OneRIBandImageToOneComplexBandImage< TInputImage, TOutputImage >
Cotb::OpeningClosingMorphologicalFilter< TInputImage, TOutputImage, TKernel >	This filter implements an opening grayscale morphological operation followed by a closing grayscale morphological operation. It tends to simplify image by obliterating details with a lower extent than the structuring element
Cotb::OverlapSaveConvolutionImageFilter< TInputImage, TOutputImage, TBoundaryCondition >
Cotb::PCAImageFilter< TInputImage, TOutputImage, TDirectionOfTransformation >	Performs a Principal Component Analysis
Cotb::PerBandVectorImageFilter< TInputImage, TOutputImage, TFilter >	This filter is a helper class to apply per band a standard itk::ImageToImageFilter to a VectorImage
►Cotb::PersistentImageFilter< TInputImage, TOutputImage >	This filter is the base class for all filter persisting data through multiple update. For instance, a filter computing global statistics on an image with streaming capabilities will have to keep the temporary results for each streamed piece of the image in order to synthesize the global statistics at the end. This filter is an itk::ImageToImageFilter, providing two additional methods. The first one, Synthetize(), allows the user to synthesize temporary data produced by the multiple updates on different pieces of the image to the global result. The second one, Reset(), allows the user to reset the temporary data for a new input image for instance
►Cotb::PersistentImageToOGRLayerFilter< TImageType >
Cotb::PersistentImageToOGRLayerSegmentationFilter< TImageType, TSegmentationFilter >
►Cotb::PersistentImageToVectorDataFilter< TVImage, TOutputVectorData >
Cotb::PersistentConnectedComponentSegmentationOBIAToVectorDataFilter< TVImage, TLabelImage, TMaskImage, TOutputVectorData >	[internal] Helper class to perform connected component segmentation on an input image, apply OBIA filtering and output a VectorData
►Cotb::PersistentImageToVectorDataFilter< TImageType, otb::LineSegmentDetector< TImageType, double >::VectorDataType >
Cotb::PersistentStreamingLineSegmentDetector< TImageType >	Perform Line segment detector in a persistent way
Cotb::DifferenceImageFilter< TInputImage, TOutputImage >	Implements comparison between two images
Cotb::FastICAInternalOptimizerVectorImageFilter< TInputImage, TOutputImage >	Internal optimisation of the FastICA unmixing filter
Cotb::PixelSuppressionByDirectionImageFilter< TInputImage, TOutputImage >	Application of a filter of suppression of isolated pixels, not belonging to a line, strating from the directions of pixels
Cotb::PixelWiseBlockMatchingImageFilter< TInputImage, TOutputMetricImage, TOutputDisparityImage, TMaskImage, TBlockMatchingFunctor >	Perform 2D block matching between two images
Cotb::PrintableImageFilter< TInputImage, TMaskImage >	This class is a helper class to turn a vector image to a generic 8 bytes RGB image. A mask can be used to highlight some objects represented by the same value. The mask is a binary image. Background MaskValue is used to precise which value of the mask are objects (default 0). Output object color can be set using m_ObjectColor (default white). The output is a 3 channel image, each channel is a channel of the input image. They can be selected using m_ChannelList or SetChannel(int ch ) method
Cotb::ROIdataConversion< TInputImage, TInputROIImage >	Image data to vector conversion
Cotb::RadiometricMomentsImageFilter< TInputImage, TOutputImage >	Calculate the radiometric moments
Cotb::ResetMarginFilter< TImage >
Cotb::SFSTexturesImageFilter< TInputImage, TOutputImage >	This functor computes the texture describes in the following publication It is based on line direction estimation
Cotb::SOMActivationBuilder< TListSample, TInputMap, TOutputImage >	This class takes a self organizing map and an input vector image, and produce a map counting the number of activation for each vector in the SOM map
Cotb::SarBurstExtractionImageFilter< TImage >	Performs a burst extraction by keeping only lines and samples of a required Burst
Cotb::SarDeburstImageFilter< TImage >	Performs a deburst operation by removing redundant lines
Cotb::ScalarImageToAdvancedTexturesFilter< TInpuImage, TOutputImage >	In this case, 10 advanced texture features will be processed. The 10 output image channels are: Mean, Variance, Dissimilarity, Sum Average, Sum Variance, Sum Entropy, Difference of Entropies, Difference of Variances, IC1 and IC2. They are provided in this exact order in the output image. The textures are computed over a sliding window with user defined radius
Cotb::ScalarImageToHigherOrderTexturesFilter< TInpuImage, TOutputImage >	This class compute 10 local higher order statistics textures coefficients based on the grey level run-length matrix
Cotb::ScalarImageToPanTexTextureFilter< TInpuImage, TOutputImage >	This class computes a texture derived built-up presence index (PanTex)
Cotb::ScalarImageToTexturesFilter< TInpuImage, TOutputImage >	This class compute 8 local Haralick textures features. The 8 output image channels are: Energy, Entropy, Correlation, Inverse Difference Moment, Inertia, Cluster Shade, Cluster Prominence and Haralick Correlation. They are provided in this exact order in the output image. Thus, this application computes the following Haralick textures over a neighborhood with user defined radius
Cotb::SimpleRcsPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >	This class performs a simple Pan sharpening operation
Cotb::SpectralAngleDistanceImageFilter< TInputImage, TOutputImage >	This filter implements the computation of the spectral angle distance with respect to a reference pixel
Cotb::StereoSensorModelToElevationFilter< TInputImage, TOutputHeight >	Using sensor models to perform correlation along epipolars
Cotb::StreamingImageVirtualWriter< TInputImage >	This class acts like a StreamingImageFileWriter, but without actually writing data to the disk
Cotb::StreamingMosaicFilterBase< TInputImage, TOutputImage, TInternalValueType >	Base class for mosaic filters. Computes the total extent of multiple inputs, and provide routines to compute whether or not an input image region must be requested
Cotb::StreamingResampleImageFilter< TInputImage, TOutputImage, TInterpolatorPrecisionType >	This class is a composite filter resampling an input image by setting a transform. The filter computes a displacement grid using the transform set and used it to warp the input
Cotb::SubPixelDisparityImageFilter< TInputImage, TOutputMetricImage, TDisparityImage, TMaskImage, TBlockMatchingFunctor >	Perform sub-pixel disparity estimation from input integer disparities and the image pair that was used
Cotb::SubsampleImageFilter< TInputImage, TOutputImage, TDirectionOfTransformation >	Performs a down sampling of an image
Cotb::SummingFilter< TInputImage, TOutputImage >	Computes the sum of the input images pixels
Cotb::SynthetizeFilter< TInputImage, TOutputImage, TFunctor >
Cotb::ThresholdVectorImageFilter< TInputImage, TOutputImage >	Set image values to a user-specified value if they are below, above, or between simple threshold values
►Cotb::TileImageFilter< TImage >	This filter allows making a spatial mosaic from a set of images
Cotb::SarConcatenateBurstsImageFilter< TImage >	This filter allows making a spatial mosaic from a set of bursts
Cotb::TwoNRIBandsImageToNComplexBandsImage< TInputImage, TOutputImage >
Cotb::UnaryFunctorNeighborhoodImageFilter< TInputImage, TOutputImage, TFunction >	Implements neighborhood-wise generic operation on image
Cotb::UnaryFunctorNeighborhoodWithOffsetImageFilter< TInputImage, TOutputImage, TFunction >	Implements neighborhood-wise generic operation on image
Cotb::UnaryFunctorWithIndexImageFilter< TInputImage, TOutputImage, TFunction >	Implements neighborhood-wise generic operation on image
Cotb::UnaryFunctorWithIndexWithOutputSizeImageFilter< TInputImage, TOutputImage, TFunction >	Implements neighborhood-wise generic operation on image
Cotb::VCAImageFilter< TVectorImage >	Estimates the endmembers present in a hyperspectral image
Cotb::VarianceImageFilter< TInputImage, TOutputImage >	Applies an averaging filter to an image
Cotb::VectorImageTo3DScalarImageFilter< TInputImage, TOutputImage >	This filter convert a 2 Dimension VectorImage to a 3 Dimension scalar image
Cotb::VectorImageToIntensityImageFilter< TInputImage, TOutputImage >	This filter implements the computation of the mean of the spectral values of each pixel
Cotb::WatershedSegmentationFilter< TInputImage, TOutputLabelImage >	Watershed composite filter allowing to set output type
Cotb::WaveletFilterBank< TInputImage, TOutputImage, TWaveletOperator, TDirectionOfTransformation >	One level stationary wavelet transform
Cotb::WaveletFilterBank< TInputImage, TOutputImage, TWaveletOperator, Wavelet::FORWARD >
Cotb::WaveletFilterBank< TInputImage, TOutputImage, TWaveletOperator, Wavelet::INVERSE >
Cotb::WaveletImageFilter< TInputImage, TOutputImage, TMotherWaveletOperator >	This filter performs wavelet forward transform. It takes three template arguments: Input, Output and WaveletOperator This filter is not streamed
Cotb::WaveletInverseImageFilter< TInputImage, TOutputImage, TMotherWaveletOperator >	This filter performs wavelet inverse transform. It takes three template arguments: Input, Output and WaveletOperator This filter is not streamed
►Citk::ImageToImageFilter< TInputImage, otb::LabelMapWithAdjacency< itk::LabelObject< typename TInputImage::PixelType, TInputImage::ImageDimension >> >
Cotb::LabelImageToLabelMapWithAdjacencyFilter< TInputImage, TOutputImage >	Convert a labeled image to a label map with adjacency information
Cotb::Functor::ImageToRadianceImageFunctor< TInput, TOutput >	Add beta to the quotient Input over alpha
Cotb::Functor::ImageToReflectanceImageFunctor< TInput, TOutput >	Call the ImageToRadianceFunctor over the input and the RadianceToReflectanceFunctor to this result
Cotb::ImageTypeDeduction< T >	Helper struct to derive ImageType from template parameter
Cotb::ImageTypeDeduction< itk::VariableLengthVector< T > >	Partial specialisation for itk::VariableLengthVector<T>
Cotb::Function::ImaginaryToComplex< TInputImageImaginaryPart, TOutput >
Cotb::Functor::IndicesStackFunctor< TIndice >	A class to compute a stack of radiometric indices
Cotb::InfoSceneCoord	Represents an InfoSceneCoord
Cotb::internal::ReprojectTransformationFunctor::InPlace
►Citk::InPlaceImageFilter
►Cotb::BinaryFunctorNeighborhoodVectorImageFilter< TInputImage1, TInputImage2, TOutputImage, Functor::KullbackLeiblerProfile< itk::ConstNeighborhoodIterator< TInputImage1 >, itk::ConstNeighborhoodIterator< TInputImage2 >, TOutputImage::PixelType > >
Cotb::KullbackLeiblerProfileImageFilter< TInputImage1, TInputImage2, TOutputImage >	Implements neighborhood-wise the computation of KullbackLeibler profile over Edgeworth approximation
►Cotb::FunctionToImageFilter< TInputImage, TOutputImage, SarBrightnessFunction< TInputImage > >
Cotb::SarBrightnessToImageFilter< TInputImage, TOutputImage >	Evaluates the SarBrightnessFunction onto a source image
►Cotb::FunctionToImageFilter< TInputImage, TOutputImage, SarRadiometricCalibrationFunction< TInputImage > >
Cotb::SarRadiometricCalibrationToImageFilter< TInputImage, TOutputImage >	Evaluates the SarRadiometricCalibrationFunction onto a source image The nature of product(TerrSARX, Sentinel1, etc..) are thus detected automatically from the metadata. The filter then reads necessary parameters required to perform SarCalibration in a generic way
►Cotb::UnaryFunctorNeighborhoodVectorImageFilter< TInputImage, TOutputImage, Functor::LocalGradientOperator< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType > >
Cotb::LocalGradientVectorImageFilter< TInputImage, TOutputImage >	Implements the 3x3 Local Gradient to be processed on a vector image
►Cotb::UnaryFunctorNeighborhoodVectorImageFilter< TInputImage, TOutputImage, Functor::HorizontalSobelOperator< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType > >
Cotb::HorizontalSobelVectorImageFilter< TInputImage, TOutputImage >	Implements the Horizontal Sobel Gradient to be processed on a vector image
►Cotb::UnaryFunctorNeighborhoodVectorImageFilter< TInputImage, TOutputImage, Functor::VerticalSobelOperator< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType > >
Cotb::VerticalSobelVectorImageFilter< TInputImage, TOutputImage >	Implements the Vertical Sobel Gradient to be processed on a vector image
►Cotb::UnaryFunctorNeighborhoodVectorImageFilter< TInputImage, TOutputImage, Functor::SobelOperator< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType > >
Cotb::SobelVectorImageFilter< TInputImage, TOutputImage >	Implements the Sobel Gradient to be processed on a vector image
►Cotb::UnaryFunctorNeighborhoodVectorImageFilter< TInputImage, TOutputImage, Functor::LocalActivityOperator< itk::ConstNeighborhoodIterator< TInputImage >, TOutputImage::PixelType > >
Cotb::LocalActivityVectorImageFilter< TInputImage, TOutputImage >	Implements the LocalActivity Gradient to be processed on a vector image
►Cotb::UnaryFunctorVectorImageFilter< TInputImage, TOutputImage, Functor::NormalizeVectorImageFunctor< TInputImage::PixelType, TOutputImage::PixelType > >
Cotb::NormalizeVectorImageFilter< TInputImage, TOutputImage >	Normalize an VectorImage by setting its mean to zero and possibly variance to one (band by band)
►Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, Functor::ReflectanceToSurfaceReflectanceImageFunctor< TInputImage::InternalPixelType, TOutputImage::InternalPixelType > >
Cotb::ReflectanceToSurfaceReflectanceImageFilter< TInputImage, TOutputImage >	Calculates the slope, the orientation incidence and exitance radius values for each pixel
Cotb::SurfaceReflectanceToReflectanceFilter< TInputImage, TOutputImage >	Calculates the slope, the orientation incidence and exitance radius values for each pixel
►Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, Functor::ReflectanceToRadianceImageFunctor< TInputImage::InternalPixelType, TOutputImage::InternalPixelType > >
►Cotb::ReflectanceToRadianceImageFilter< TInputImage, TOutputImage >	Convert reflectance value into radiance value
Cotb::ReflectanceToLuminanceImageFilter< TInputImage, TOutputImage >	Convert reflectance value into radiance value
►Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, Functor::ImageToRadianceImageFunctor< TInputImage::InternalPixelType, TOutputImage::InternalPixelType > >
►Cotb::ImageToRadianceImageFilter< TInputImage, TOutputImage >	Convert a raw value into a radiance value
Cotb::ImageToLuminanceImageFilter< TInputImage, TOutputImage >	Convert a raw value into a Luminance value
►Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, Functor::ReflectanceToImageImageFunctor< TInputImage::InternalPixelType, TOutputImage::InternalPixelType > >
Cotb::ReflectanceToImageImageFilter< TInputImage, TOutputImage >	Convert a reflectance into a raw value value
►Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, Functor::RadianceToReflectanceImageFunctor< TInputImage::InternalPixelType, TOutputImage::InternalPixelType > >
►Cotb::RadianceToReflectanceImageFilter< TInputImage, TOutputImage >	Convert radiance value into reflectance value
Cotb::LuminanceToReflectanceImageFilter< TInputImage, TOutputImage >	Convert radiance value into reflectance value
►Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, Functor::RadianceToImageImageFunctor< TInputImage::InternalPixelType, TOutputImage::InternalPixelType > >
►Cotb::RadianceToImageImageFilter< TInputImage, TOutputImage >	Convert a radiance value into raw image value
Cotb::LuminanceToImageImageFilter< TInputImage, TOutputImage >	Convert a radiance value into raw image value
►Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, Functor::ImageToReflectanceImageFunctor< TInputImage::InternalPixelType, TOutputImage::InternalPixelType > >
Cotb::ImageToReflectanceImageFilter< TInputImage, TOutputImage >	Convert a raw value into a reflectance value
Cotb::BandMathImageFilter< TImage >	Performs a mathematical operation on the input images according to the formula specified by the user
Cotb::BinaryFunctorNeighborhoodVectorImageFilter< TInputImage1, TInputImage2, TOutputImage, TFunction >	Implements neighborhood-wise generic operation of two images being vector images
Cotb::BoxAndWhiskerImageFilter< TInputImage >	This class performs the detection of outlier with the Box and Whisker technique
Cotb::CastImageFilter< TInputImage, TOutputImage >	Casts input pixels to output pixel type
Cotb::FunctionToImageFilter< TInputImage, TOutputImage, TFunction >	Evaluates a ImageFunction onto a source image
Cotb::FunctionWithNeighborhoodToImageFilter< TInputImage, TOutputImage, TFunction >	Evaluates a ImageFunction onto a source image
Cotb::InPlacePassFilter< TInputImage >	This filter has the only purpose to recall regions
Cotb::KMeansImageClassificationFilter< TInputImage, TOutputImage, VMaxSampleDimension, TMaskImage >	This filter performs the classification of a VectorImage using a KMeans estimation result
Cotb::MultiChannelsPolarimetricSynthesisFilter< TInputImage, TOutputImage, TFunction >	This class computes the polarimetric synthesis from two to four radar images, depending on the polarimetric architecture
Cotb::NormalizeInnerProductPCAImageFilter< TInputImage, TOutputImage >	The aim of the class is to normalise vector images using a vector coefficient values
Cotb::QuaternaryFunctorImageFilter< TInputImage1, TInputImage2, TInputImage3, TInputImage4, TOutputImage, TFunction >	Implements pixel-wise generic operation of four images
Cotb::SOMImageClassificationFilter< TInputImage, TOutputImage, TSOMMap, TMaskImage >	This filter performs the classification of a VectorImage using a given SOM map
Cotb::UnaryFunctorNeighborhoodVectorImageFilter< TInputImage, TOutputImage, TFunction >	Implements neighborhood-wise generic operation of one vector image
Cotb::UnaryFunctorVectorImageFilter< TInputImage, TOutputImage, TFunction >	Implements neighborhood-wise generic operation of one vector image
Cotb::UnaryImageFunctorWithVectorImageFilter< TInputImage, TOutputImage, TFunction >	Applies a functor to a VectorImage
►Citk::InPlaceLabelMapFilter
►Cotb::LabelMapFeaturesFunctorImageFilter< TImage, Functor::StatisticsAttributesLabelObjectFunctor< TImage::LabelObjectType, TFeatureImage > >
Cotb::StatisticsAttributesLabelMapFilter< TImage, TFeatureImage >	This class is a fork of itk::StasticsLabelMapFilter to support AttributesMapLabelObject
►Cotb::LabelMapFeaturesFunctorImageFilter< TImage, Functor::ShapeAttributesLabelObjectFunctor< TImage::LabelObjectType, Image< typename TImage::PixelType, TImage::ImageDimension > > >
Cotb::ShapeAttributesLabelMapFilter< TImage, TLabelImage >	This class is a fork of the itk::ShapeLabelMapFilter working with AttributesMapLabelObject
►Cotb::LabelMapFeaturesFunctorImageFilter< TImage, Functor::NormalizeAttributesLabelObjectFunctor< TImage::LabelObjectType > >
Cotb::NormalizeAttributesLabelMapFilter< TImage >	This class works with AttributesMapLabelObject, and normalizes all attributes wrt a map of minimal and maximal attribute value, such that the resulting attributes are in the [0, 1] interval
►Cotb::LabelMapFeaturesFunctorImageFilter< TImage, Functor::BandStatsAttributesLabelObjectFunctor< TImage::LabelObjectType, otb::Image< double, 2 > > >
Cotb::BandsStatisticsAttributesLabelMapFilter< TImage, TFeatureImage >	This filter computes band statistics attributes for each object
Cotb::HooverInstanceFilter< TLabelMap >	This class computes the Hoover instances
Cotb::LabelMapClassifier< TInputLabelMap >	Classify each LabelObject of the input LabelMap in place
Cotb::LabelMapFeaturesFunctorImageFilter< TImage, TFunctor >	This class applies a functor to compute new features
Cotb::LabelObjectOpeningMuParserFilter< TImage, TFunction >
Cotb::Wrapper::CompositeApplication::InternalApplication
►Citk::InterpolateImageFunction
►Cotb::BCOInterpolateImageFunctionBase< TInputImage, double >
Cotb::BCOInterpolateImageFunction< TInputImage, TCoordRep >	Interpolate an image at specified positions using bicubic interpolation
►Cotb::BCOInterpolateImageFunctionBase< otb::VectorImage< TPixel, VImageDimension >, TCoordRep >
Cotb::BCOInterpolateImageFunction< otb::VectorImage< TPixel, VImageDimension >, TCoordRep >
►Cotb::GenericInterpolateImageFunction< TInputImage, Function::ProlateFunction< double, double >, itk::ConstantBoundaryCondition< TInputImage >, double >
Cotb::ProlateInterpolateImageFunction< TInputImage, TBoundaryCondition, TCoordRep, TInputInterpolator, TOutputInterpolator >	Prolate interpolation of an otb::image
►Cotb::GenericInterpolateImageFunction< TInputImage, TWindowFunction, itk::ZeroFluxNeumannBoundaryCondition< TInputImage >, double >
Cotb::WindowedSincInterpolateImageFunctionBase< TInputImage, TWindowFunction, TBoundaryCondition, TCoordRep >	Use the windowed sinc function to interpolate
Cotb::BCOInterpolateImageFunctionBase< TInputImage, TCoordRep >
Cotb::BSplineInterpolateImageFunction< TImageType, TCoordRep, TCoefficientType >	This class is an evolution of the itk::BSplineInterpolateImageFunction to handle huge images with this interpolator. For more documentation, please refer to the original class
►Cotb::GenericInterpolateImageFunction< TInputImage, TFunction, TBoundaryCondition, TCoordRep >	Generic interpolation of an otb::Image
►Cotb::WindowedSincInterpolateImageFunctionBase< TInputImage, Function::GaussianWindowFunction< double, double >, itk::ZeroFluxNeumannBoundaryCondition< TInputImage >, double >
Cotb::WindowedSincInterpolateImageGaussianFunction< TInputImage, TBoundaryCondition, TCoordRep, TInputInterpolator, TOutputInterpolator >	Use the WindowedSincInterpolateImageFunctionBase with a Gaussian Function
►Cotb::WindowedSincInterpolateImageFunctionBase< TInputImage, Function::WelchWindowFunction< double, double >, itk::ConstantBoundaryCondition< TInputImage >, double >
Cotb::WindowedSincInterpolateImageWelchFunction< TInputImage, TBoundaryCondition, TCoordRep, TInputInterpolator, TOutputInterpolator >	Use the WindowedSincInterpolateImageFunctionBase with a Welch Function
►Cotb::WindowedSincInterpolateImageFunctionBase< TInputImage, Function::BlackmanWindowFunction< double, double >, itk::ConstantBoundaryCondition< TInputImage >, double >
Cotb::WindowedSincInterpolateImageBlackmanFunction< TInputImage, TBoundaryCondition, TCoordRep, TInputInterpolator, TOutputInterpolator >	Use the WindowedSincInterpolateImageFunctionBase with a Blackman Function
►Cotb::WindowedSincInterpolateImageFunctionBase< TInputImage, Function::LanczosWindowFunction< double, double >, itk::ConstantBoundaryCondition< TInputImage >, double >
Cotb::WindowedSincInterpolateImageLanczosFunction< TInputImage, TBoundaryCondition, TCoordRep, TInputInterpolator, TOutputInterpolator >	Use the WindowedSincInterpolateImageFunctionBase with a Lanczos Function
►Cotb::WindowedSincInterpolateImageFunctionBase< TInputImage, Function::CosineWindowFunction< double, double >, itk::ConstantBoundaryCondition< TInputImage >, double >
Cotb::WindowedSincInterpolateImageCosineFunction< TInputImage, TBoundaryCondition, TCoordRep, TInputInterpolator, TOutputInterpolator >	Use the WindowedSincInterpolateImageFunctionBase with a Cosine Function
►Cotb::WindowedSincInterpolateImageFunctionBase< TInputImage, Function::HammingWindowFunction< double, double >, itk::ConstantBoundaryCondition< TInputImage >, double >
Cotb::WindowedSincInterpolateImageHammingFunction< TInputImage, TBoundaryCondition, TCoordRep, TInputInterpolator, TOutputInterpolator >	Use the WindowedSincInterpolateImageFunctionBase with a Hamming Function
Cotb::Interval
►Cmup::IOprtBin
Cotb::DivisionByScalar
Cotb::ElementWiseDivision
Cotb::ElementWiseMultiplication
Cotb::ElementWisePower
Cotb::MultiplicationByScalar
Cotb::PowerByScalar
Cotb::Functor::ISRAUnmixingFunctor< TInput, TOutput, TPrecision >	Perform fully constrained least squares on a pixel
Cotb::ObjectList< TObject >::Iterator	Iterator of the object list
Cotb::internals::ZipIterator< TImageIterator, ConstOrMutable >::PixelListProxy::iterator__
►Cboost::iterator_facade
Cotb::ogr::DataSource::layer_iter< Value >	Implementation class for Layer iterator
Cotb::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
Cotb::Functor::JoinHistogramMI< TInput1, TInput2, TOutput >
Cotb::Meanshift::KernelGaussian
Cotb::Meanshift::KernelUniform
Cotb::MetaDataKey::KeyTypeDef
Cotb::Functor::KullbackLeiblerDistance< TInput1, TInput2, TOutput >	Functor for KullbackLeiblerDistanceImageFilter. Please refer to KullbackLeiblerDistanceImageFilter
Cotb::Functor::KullbackLeiblerProfile< TInput1, TInput2, TOutput >	Functor for KullbackLeiblerProfileImageFilter. Please refer to KullbackLeiblerProfileImageFilter
Cotb::Functor::KullbackLeiblerSupervizedDistance< TInput1, TInput2, TInputROIImage, TOutput >	Functor for KullbackLeiblerSupervizedDistanceImageFilter. Please refer to KullbackLeiblerSupervizedDistanceImageFilter
Cotb::Functor::LAB2RGB< TInput, TOutput >	Base class for converting LAB into RGB color space (Ruderman et al.)
Cotb::LabeledOutputAccessor< TFilter >	Accessor to the index of the labeled output image of the Template Filter
Cotb::LabeledOutputAccessor< MeanShiftSmoothingImageFilter< TInputImage, TOutputImage, TOutputImage2, TKernelType > >
►Citk::LabelMap
Cotb::LabelMapWithAdjacency< TLabelObject >	This class is a LabelMap with additional adjacency information
►Citk::LabelMapFilter
Cotb::HooverMatrixFilter< TLabelMap >	This class computes the confusion matrix from two LabelMapObject
Cotb::LabelMapToAttributeImageFilter< TInputImage, TOutputImage, TAttributeAccessor >	This class produces an image from attributes in a label map
Cotb::LabelMapToSimulatedImageFilter< TInputLabelMap, TSimuStep1, TSimuStep2, TOutputImage >	Transform a labelMap into an image
Cotb::LabelMapWithClassLabelToClassLabelImageFilter< TInputImage, TOutputImage >	Converts a LabelMap<LabelObjectWithClassLabel> to an image of class labels
Cotb::MinMaxAttributesLabelMapFilter< TInputImage >	Computes the min/max of all attributes of a LabelMap where LabelObject type is compatible with otb::AttributesMapLabelObject
►Citk::LabelMapToLabelImageFilter
Cotb::LabelMapToLabelImageFilter< TInputImage, TOutputImage >	Converts a LabelMap to a labeled image
►Citk::LabelObject
►Cotb::AttributesMapLabelObject< TLabel, VImageDimension, TAttributesValue >	A LabelObject with a generic attributes map
Cotb::AttributesMapLabelObjectWithClassLabel< TLabel, VImageDimension, TAttributesValue, TClassLabel >	An AttributesMapLabelObject with an optional class label
Cotb::Functor::LabelObjectFieldsFunctor< TLabelObject >	Returns additional OGR fields to be saved in VectorData
Cotb::Functor::LabelObjectFieldsFunctor< typename TLabelMap::LabelObjectType >
CLabelObjectOpeningMuParserImageFilter	Label Object opening using shape and radiometric attributes. Acception/rejection criteria is user defined via MuParser function
Cotb::Functor::LabelObjectToPolygonFunctor< TLabelObject, TPolygon >	This class vectorizes a LabelObject to a Polygon
Cotb::Functor::LabelObjectWithClassLabelFieldsFunctor< TLabelObject >	Returns additional OGR fields to be saved in VectorData
Cotb::Functor::LabelToBoundaryFunctor< TInput, TOutput >	Functor to extract segmentation boundaries
Cotb::LagrangianOrbitInterpolator
Cotb::Function::LanczosWindowFunction< TInput, TOutput >	Window function for sinc interpolation
►Cotb::Functor::LandsatTM::LandsatTMIndexBase< TInput, TOutput >	Base class for Landsat-TM indices
►Cotb::Functor::LandsatTM::KernelSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::BarrenLandOrBuiltUpOrCloudsSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::DominantBlueSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::FlatResponseBarrenLandOrBuiltUpSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::PitbogOrGreenhouseSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::RangelandSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::ShadowCloudOrSnowSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::ShadowWithBarrenLandSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::ShadowWithVegetationSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::SnowOrIceSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::SpectralRuleBasedClassifier< TInput, TOutput >	Implementation of the SpectralRuleBasedClassifier for Landsat TM image land cover classification as described in table IV of Baraldi et al. 2006, "Automatic Spectral Rule-Based Preliminary Mapping of Calibrated Landsat TM and ETM+ Images", IEEE Trans. on Geoscience and Remote Sensing, vol 44, no 9. This classifier assumes that the input image is calibrated in reflectances and in temperature. The reflectances can be given in the 0-1 range (Normalized) or in 0-1000 (Thousands). Temperatures can be given in Kelvin, in Kelvin*100 or in Celsius. Appropriate accessors are available for setting these units
Cotb::Functor::LandsatTM::ThickCloudsSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::ThinCloudsSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::VegetationSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::WaterOrShadowSpectralRule< TInput, TOutput >
Cotb::Functor::LandsatTM::WetlandSpectralRule< TInput, TOutput >
►Cotb::Functor::LandsatTM::LandsatTMIndex< TInput, TOutput >
Cotb::Functor::LandsatTM::BIO< TInput, TOutput >
Cotb::Functor::LandsatTM::Bright< TInput, TOutput >
Cotb::Functor::LandsatTM::MIR1< TInput, TOutput >
Cotb::Functor::LandsatTM::MIR2< TInput, TOutput >
Cotb::Functor::LandsatTM::MIRTIR< TInput, TOutput >
Cotb::Functor::LandsatTM::NDBBBI< TInput, TOutput >
Cotb::Functor::LandsatTM::NDBSI< TInput, TOutput >
Cotb::Functor::LandsatTM::NDSI< TInput, TOutput >
Cotb::Functor::LandsatTM::NDSIVis< TInput, TOutput >
Cotb::Functor::LandsatTM::NDVI< TInput, TOutput >
Cotb::Functor::LandsatTM::NIR< TInput, TOutput >
Cotb::Functor::LandsatTM::TIR< TInput, TOutput >
Cotb::Functor::LandsatTM::Vis< TInput, TOutput >
►Cotb::Functor::LandsatTM::LandsatTMIndexBase< TInput, itk::FixedArray< unsigned int, 11 > >
Cotb::Functor::LandsatTM::LinguisticVariables< TInput >
CLandsatTMLinguisticVariables
Cotb::ogr::Layer	Layer of geometric objects
Cotb::OGRExtendedFilenameToOptions::LayerOptionType
►CLayoutPolicy
Cotb::details::generic_layout< LayoutPolicy >::mapping< Extents >
►Cboost::less_than_comparable
Cotb::MetaData::Duration	Represents a duration
Cotb::MetaData::TimePoint	Represents a point in Time
Cotb::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
Cotb::Functor::LHMI< TInput1, TInput2, TOutput >	TODO
►Citk::LightObject
Cotb::EigenvalueLikelihoodMaximisation< TPrecision >	Estimates the number of endmembers in a hyperspectral image
Cotb::Functor::MaskMuParserFunctor< TInputPixel >
Cotb::GDALDatasetWrapper
Cotb::GreyLevelCooccurrenceIndexedList< TPixel >	This class holds a VectorType of CooccurrencePairType with each pair is a combination of pixel index and frequency
Cotb::Parser	Definition of the standard floating point parser. Standard implementation of the mathematical expressions parser
Cotb::ParserX	Definition of the standard floating point parser. Standard implementation of the mathematical expressions parser
Cotb::PleiadesPToXSAffineTransformCalculator	Compute the affine transform linking P and XS pixel position for Pleiades sensor bundles
Cotb::QuadraticallyConstrainedSimpleSolver< ValueType >	Solves the optimisation problem for radiometric harmonisation of multiple overlapping images
►Cotb::SarCalibrationLookupData
Cotb::Radarsat2CalibrationLookupData
Cotb::Sentinel1CalibrationLookupData	Computes the Sentinel 1 calibration contribution for the given pixel using a LUT. Depending on how it is initialized, the LUT can be a ALPHA, BETA, SIGMA or DN calibration LUT
Cotb::Sentinel1ThermalNoiseLookupData	Calculate the Sentinel 1 thermal noise contribution for the given pixel
Cotb::VirtualDimensionality< TPrecision >	Estimates the number of endmembers in a hyperspectral image with the Virtual Dimensionality (HFC) method
Cotb::WaveletGenerator< TMotherWaveletOperator >	Wavelet coefficient definition
►Citk::LightProcessObject
►Cotb::ImageIOBase	Abstract superclass defines image IO interface
Cotb::GDALImageIO	ImageIO object for reading and writing images with GDAL
►Cotb::VectorDataIOBase	Abstract superclass defines VectorData IO interface
Cotb::OGRVectorDataIO	ImageIO object for reading and writing OGR format vector data
CGapFilling::LinearGapFillingFunctor< PixelType >
Cotb::SarSensorModel::LineSampleYZ
Cotb::Wrapper::ListViewParameter::ListViewChoice
Cotb::Functor::LocalActivityOperator< TInput, TOutput >	Performs the calculation of LocalActivity derivation
Cotb::Functor::LocalGradientOperator< TInput, TOutput >	Performs the calculation of LocalGradient derivation
CLocalRxDetectionFunctor	This functor computes a local Rx score on an input neighborhood. Pixel of the neighborhood inside the internal radius are not considered during the computation of local statistics
Cotb::Functor::LocalRxDetectionFunctor< TInput, TOutput >
Cotb::Functor::Log10Thresholded< TInput, TOutput >
►Citk::Logger
Cotb::Logger	An ITK logger specialized for OTB
Cotb::Functor::LPBlockMatching< TInputImage, TOutputMetricImage >	Functor to perform block-matching based on the L^p pseudo-norm
Cotb::MetaData::LUT< VDim >
Cotb::MetaData::LUTAxis
Cotb::Functor::MagnitudeFunctor< TInputPixel, TOutputPixel >	This functor computes the magnitude of a covariant vector
Cotb::functor_filter_details::MakeIterator< N >
Cotb::functor_filter_details::MakeIterator< std::false_type >
Cotb::functor_filter_details::MakeIterator< std::true_type >
Cotb::Wrapper::MapProjectionParametersHandler	This class represent a helper class
Cotb::MaskedIteratorDecorator< TIteratorType, TMaskIteratorType >	Decorate an iterator to ignore masked pixels
Cotb::Functor::MaskFunctor< TInputPixel, TMaskPixel, TOutputPixel >	Output is a InputPixel if MaskPixel is m_Background and a defined other value (m_ObjectColor) otherwise
CMaskMuParserFunctor	Functor used to create binary mask for input of connected component segmentation module
CMaskMuParserImageFilter	Performs a mathematical operation on the input images according to the formula specified by the user. values different from 0 are set to 1
Cotb::Functor::MultiScaleConvexOrConcaveDecisionRule_tags::max_closing_profile_derivative
Cotb::Functor::MultiScaleConvexOrConcaveDecisionRule_tags::max_opening_profile_derivative
Cotb::Functor::MeanDifference< TInput1, TInput2, TOutput >
Cotb::Functor::MeanFilterFunctor< TInput1, TOutput >
Cotb::Functor::MeanFunctor< TInput, TOutputValue >	This functor generate the mean value of a component pixels
Cotb::Functor::MeanRatio< TInput1, TInput2, TOutput >
Cotb::ogr::internal::MemberContainerGetterPtr< T, ptr_to_function, FinalReturnType >
Cotb::ogr::internal::MemberContainerSetterPtr< T, ptr_to_function, ActualParamType >
Cotb::ogr::internal::MemberGetterPtr< T, ptr_to_function, FinalReturnType >
Cotb::ogr::internal::MemberSetterPtr< T, ptr_to_function, ActualParamType >
Cotb::Functor::MergeLabelObjectFunctor< TLabelObject >	Merge two LabelObjects
►Cotb::MetadataStorageInterface	Base class to store metadata information in files/images
Cotb::GDALImageIO	ImageIO object for reading and writing images with GDAL
►Cotb::MetadataSupplierInterface	Base class to access metadata information in files/images
Cotb::GDALImageIO	ImageIO object for reading and writing images with GDAL
Cotb::GeomMetadataSupplier	Class to access metadata information in a Geom file
Cotb::XMLMetadataSupplier	Class to access metadata information in a XML file
Cotb::MLMSampleTraitsImpl< TInput, isNumber >
Cotb::MLMTargetTraitsImpl< TInput, isNumber >
Cotb::ogr::DataSource::Modes
►Citk::MorphologyImageFilter
Cotb::NeighborhoodMajorityVotingImageFilter< TInputImage, TOutputImage, TKernel >
Cotb::Functor::MuellerToPolarisationDegreeAndPowerFunctor< TInput, TOutput >	Evaluate the min and max polarisation degree and min and max power from the Mueller image
Cotb::Functor::MuellerToReciprocalCovarianceFunctor< TInput, TOutput >	Evaluate the MLC image from the Mueller image
CGapFilling::MultiComponentTimeSeriesFunctorAdaptor< PixelType, FunctorType >
►Cboost::multipliable2
Cotb::MetaData::Duration	Represents a duration
Cotb::Functor::MultiplyByScalar< TInput, TOutput >
Cotb::Functor::MultiplyVectorImageFilterFunctor< TInput1, TInput2, TOutputPixel >
Cotb::Functor::MultiScaleConvexOrConcaveDecisionRule< TInput, TLabeled >	This Functor apply a classification rule on two membership value along with two labels
Cotb::internals::MutableTag
Cotb::narrow
Cotb::Functor::NCCBlockMatching< TInputImage, TOutputMetricImage >	Functor to perform simple NCC block-matching
Cotb::NeatRegionLogger
►Citk::NeighborhoodOperator
►Cotb::WaveletOperatorBase< TMotherWaveletOperator, TPixel, VDimension, itk::NeighborhoodAllocator< TPixel > >
Cotb::WaveletHighPassOperator< TMotherWaveletOperator, TDirectionOfTransformation, TPixel, VDimension, TAllocator >	Specific implementation of the mother wavelet part of wavelet transformator
Cotb::WaveletLowPassOperator< TMotherWaveletOperator, TDirectionOfTransformation, TPixel, VDimension, TAllocator >	Specific implementation of scale part of wavelet transformator
Cotb::WaveletOperatorBase< TMotherWaveletOperator, TPixel, VDimension, TAllocator >	A NeighborhoodOperator wavelet base class
Cotb::sampleAugmentation::NeighborSorter
Cgrm::NeighborType< DerivedNode >
Cotb::sampleAugmentation::NeighborType
Cotb::Functor::NoDataFunctor< TInputPixel, TOutputPixel >	Functor used by ImageToNoDataMaskFilter
Cotb::SimpleRcsPanSharpeningFusionImageFilter< TPanImageType, TXsImageType, TOutputImageType, TInternalPrecision >::NoDataFusionFunctor
►Cboost::noncopyable
►Cotb::DataObjectListInterface
Cotb::ObjectList< TImage >
Cotb::ObjectList< SamplingRateCalculator >
Cotb::ObjectList< TObject >	This class is a generic all-purpose wrapping around an std::vector<itk::SmartPointer<ObjectType> >
►Cotb::GeometriesSource
►Cotb::GeometriesToGeometriesFilter
Cotb::DefaultGeometriesToGeometriesFilter< TransformationFunctor, FieldTransformationPolicy >
Cotb::GeometriesProjectionFilter
Cotb::SensorTransformFactory	Creates an instance of SensorTransform (RPC, SAR ...) object using object factory
Cotb::ogr::DataSource	Collection of geometric objects
Cotb::Functor::NormalizeAttributesLabelObjectFunctor< TLabelObject >	Functor to normalize all attributes of a LabelMap
Cotb::Functor::NormalizeVectorImageFunctor< TInput, TOutput >	NormalizeVectorImageFunctor
Cotb::NotNull< T >
Cotb::NotNull< PixelType * >
Cotb::mpl::internals::NumberOfComponents< PixelType >
Cotb::mpl::internals::NumberOfComponents< itk::VariableLengthVector< RealType > >
Cotb::mpl::internals::NumberOfComponents< std::complex< T > >
Cotb::mpl::internals::NumberOfComponents< T const >
Cotb::functor_filter_details::NumberOfOutputComponents< F, O, N >
Cotb::functor_filter_details::NumberOfOutputComponents< F, otb::Image< T >, N >
Cotb::functor_filter_details::NumberOfOutputComponents< F, otb::VectorImage< T >, N >
COBIAMuParserFunctor	Use MuParser criteria to accept/reject LabelObject given his shape and radiometrics statistics. This functor is based on the mathematical parser library muParser. The built in functions and operators list is available at: http://muparser.sourceforge.net/mup_features.html#idDef2
Cotb::Functor::OBIAMuParserFunctor< TLabelObject >
Cotb::Functor::OBIAMuParserFunctor< typename TImage::LabelObjectType >
►Citk::Object
►Cotb::MachineLearningModel< itk::VariableLengthVector< TInputValue >, itk::VariableLengthVector< TInputValue > >
Cotb::AutoencoderModel< TInputValue, NeuronType >
Cotb::PCAModel< TInputValue >
Cotb::SOMModel< TInputValue, MapDimension >
►Cotb::StreamingManager< TInputImage >
Cotb::StreamingShrinkStreamingManager< TInputImage >
Cotb::BilinearProjection	Computes a bilinear projection after init with reference points
Cotb::ConfusionMatrixCalculator< TRefListLabel, TProdListLabel >
Cotb::ConfusionMatrixMeasurements< TConfusionMatrix, TLabel >
Cotb::ContingencyTable< TClassLabel >
Cotb::ContingencyTableCalculator< TClassLabel >	ContingencyTableCalculator provide facilities to compute ContingencyTable
Cotb::ContinuousMinimumMaximumImageCalculator< TInputImage >	Compute the continuous maximum and the minimum of an image
Cotb::CoordinateToName	Retrieve geographical information for longitude and latitude coordinates
►Cotb::CurlHelperInterface	Class to use the curl capabilities from OTB
Cotb::CurlHelper	Class to use the curl capabilities from OTB
Cotb::CurlHelperStub	Class to test classes using the curl capabilities from OTB
Cotb::DataNode< TPrecision, VDimension, TValuePrecision >	This class represents a node of data in a vector data hierarchy
►Cotb::ExtendedFilenameHelper	Helper to handle extended filenames
Cotb::ExtendedFilenameToReaderOptions	Converts an extended filename to reader options
Cotb::ExtendedFilenameToWriterOptions	Converts an extended filename to writer options
Cotb::OGRExtendedFilenameToOptions	This class aim at processing GDAL option that can be pass through extended filename
Cotb::FullyDecomposedWaveletPacketCost< TImage >	Cost evaluation to be used into the Wavelet Packet decomposition class
►Cotb::Function::ChannelSelectorFunctor< TInputPixel >	Base class for pixel representation functions
Cotb::Function::AmplitudeFunctor< TInputPixel >	Compute the module from the selected channel in the input
Cotb::Function::PhaseFunctor< TInputPixel >	Compute the module from the selected channel in the input
Cotb::GaborFilterGenerator< TPrecision >
Cotb::ImageIOFactory	Creation of object instance using object factory
►Cotb::ImageMetadataInterfaceBase	Base class for captor metadata reading
Cotb::DefaultImageMetadataInterface	Creation of an "otb" DefaultImageMetadataInterface that gets metadata
Cotb::GDALImageMetadataInterface
►Cotb::OpticalImageMetadataInterface	Class for Optical captor metadata reading
Cotb::FormosatImageMetadataInterface	Creation of an "otb" FormosatImageMetadataInterface that gets metadata
Cotb::IkonosImageMetadataInterface	Creation of an "otb" IkonosImageMetadataInterface that gets metadata
Cotb::OpticalDefaultImageMetadataInterface	Creation of an "otb" DefaultImageMetadataInterface that gets metadata
Cotb::PleiadesImageMetadataInterface	Creation of an "otb" PleiadesImageMetadataInterface that gets metadata
Cotb::QuickBirdImageMetadataInterface	Creation of an "otb" QuickBirdImageMetadataInterface that gets metadata
Cotb::Spot6ImageMetadataInterface	Creation of an "otb" Spot6ImageMetadataInterface that gets metadata
Cotb::SpotImageMetadataInterface	Creation of an "otb" SpotImageMetadataInterface that gets metadata
Cotb::WorldView2ImageMetadataInterface	Creation of an "otb" WorldView2ImageMetadataInterface that gets metadata
►Cotb::SarImageMetadataInterface	Class for SAR captor metadata reading
Cotb::CosmoImageMetadataInterface	Creation of an "otb" CosmoImageMetadataInterface that gets metadata
Cotb::Radarsat2ImageMetadataInterface	Creation of an "otb" Radarsat2ImageMetadataInterface that gets metadata
Cotb::SarDefaultImageMetadataInterface	Creation of an "otb" DefaultImageMetadataInterface that gets metadata
Cotb::Sentinel1ImageMetadataInterface	Creation of an "otb" Sentinel1ImageMetadataInterface that gets metadata
Cotb::TerraSarXSarImageMetadataInterface	Creation of an "otb" TerraSarXSarImageMetadataInterface that gets metadata
Cotb::ImageMetadataInterfaceFactory	Create instances of ImageMetadataInterfaceFactory objects using an object factory
Cotb::ImageToGenericRSOutputParameters< TImage >	This class is a helper class to estimate the output parameters of an image after projection in a target SRS (defined here using its projectionRef)
Cotb::KMeansAttributesLabelMapFilter< TInputImage >	Execute a KMeans on the attributes of a itk::LabelMap<otb::AttributesMapLabelObject>
Cotb::LeastSquareAffineTransformEstimator< TPoint >	This class provide the affine transform LSQR estimation
Cotb::LeastSquareBilinearTransformEstimator< TPoint >	This class provide the 2D Bilinear transform LSQR estimation
Cotb::LineOfSightOptimizer< TPrecision, TLabel >	Compute the position of a 3D point from a set of N lines of sight
►Cotb::MRFEnergy< TInput1, TInput2 >	This is the base class for energy function used in the MRF framework
Cotb::MRFEnergyEdgeFidelity< TInput1, TInput2 >	This is the implementation of an edge preserving model for Markov denoising
Cotb::MRFEnergyFisherClassification< TInput1, TInput2 >	Fisher model for Markov classification
Cotb::MRFEnergyGaussian< TInput1, TInput2 >	This is the implementation of the Gaussian model for Markov classification
Cotb::MRFEnergyGaussianClassification< TInput1, TInput2 >	This is the implementation of the Gaussian model for Markov classification
Cotb::MRFEnergyPotts< TInput1, TInput2 >	This is the implementation of the Potts model for Markov classification
Cotb::MRFEnergy< TInput2, TInput2 >
►Cotb::MRFOptimizer	This is the base class for optimizer used in the MRF framework
Cotb::MRFOptimizerICM	This is the optimizer class implementing the ICM algorithm
Cotb::MRFOptimizerMetropolis	This is the optimizer class implementing the Metropolis algorithm
►Cotb::MRFSampler< TInput1, TInput2 >	This is the base class for sampler methods used in the MRF framework
Cotb::MRFSamplerMAP< TInput1, TInput2 >	This is the base class for sampler methods used in the MRF framework
Cotb::MRFSamplerRandom< TInput1, TInput2 >	This is the base class for sampler methods used in the MRF framework
Cotb::MRFSamplerRandomMAP< TInput1, TInput2 >	This is the base class for sampler methods used in the MRF framework
►Cotb::MachineLearningModel< TInputValue, TTargetValue, TConfidenceValue >	MachineLearningModel is the base class for all classifier objects (SVM, KNN, Random Forests, Artificial Neural Network, ...) implemented in the supervised classification framework of the OTB
Cotb::BoostMachineLearningModel< TInputValue, TTargetValue >
Cotb::DecisionTreeMachineLearningModel< TInputValue, TTargetValue >
Cotb::KNearestNeighborsMachineLearningModel< TInputValue, TTargetValue >
Cotb::LibSVMMachineLearningModel< TInputValue, TTargetValue >
Cotb::NeuralNetworkMachineLearningModel< TInputValue, TTargetValue >
Cotb::NormalBayesMachineLearningModel< TInputValue, TTargetValue >
Cotb::RandomForestsMachineLearningModel< TInputValue, TTargetValue >
Cotb::SVMMachineLearningModel< TInputValue, TTargetValue >	OpenCV implementation of SVM algorithm
Cotb::SharkKMeansMachineLearningModel< TInputValue, TTargetValue >
Cotb::SharkRandomForestsMachineLearningModel< TInputValue, TTargetValue >
►Cotb::MachineLearningModelFactoryBase	Base class for the MachinelearningModelFactory
Cotb::DimensionalityReductionModelFactory< TInputValue, TOutputValue >
Cotb::MachineLearningModelFactory< TInputValue, TOutputValue >	Creation of object instance using object factory
Cotb::OGRIOHelper	This class IO OGR
Cotb::OpticalImageMetadataInterfaceFactory	Create instances of OpticalImageMetadataInterfaceFactory objects using an object factory
Cotb::PipelineMemoryPrintCalculator	Estimate pipeline memory usage and optimal stream divisions
Cotb::PlaceNameToLonLat	Retrieve Longitude and Latitude coordinates from a place name
Cotb::Rectangle< TValue >	This class represent a Rectangle
►Cotb::SamplerBase	This is a base class for sampling methods
Cotb::PatternSampler	Periodic sampler for iteration loops
Cotb::PeriodicSampler	Periodic sampler for iteration loops
Cotb::RandomSampler	Random sampler for iteration loops
Cotb::SamplingRateCalculator	This class is a sampling rate calculator
Cotb::SarImageMetadataInterfaceFactory	Create instances of SarImageMetadataInterfaceFactory objects using an object factory
►Cotb::Statistics::ModelComponentBase< TSample >	Base class for distribution representation that supports analytical way to update the distribution parameters
Cotb::Statistics::GaussianModelComponent< TSample >	Component (derived from ModelComponentBase) for Gaussian class. This class is used in SEMClassifier
Cotb::StatisticsXMLFileReader< TMeasurementVector >	Read a xml file where are stored several statistics
Cotb::StatisticsXMLFileWriter< TMeasurementVector >	Write in a xml file the values stored in a MeasurementVector set as input
►Cotb::StreamingManager< TImage >	This class handles the streaming process used in the writers implementation
Cotb::NumberOfDivisionsStrippedStreamingManager< TImage >	This class computes the divisions needed to stream an image by strips, driven by a user-defined number of divisions in which to divide the images
Cotb::NumberOfDivisionsTiledStreamingManager< TImage >	This class computes the divisions needed to stream an image by strips, driven by a user-defined number of divisions in which to divide the images
Cotb::NumberOfLinesStrippedStreamingManager< TImage >	This class computes the divisions needed to stream an image by strips, driven by a user-defined desired number of lines per strips
Cotb::RAMDrivenAdaptativeStreamingManager< TImage >	This class computes the divisions needed to stream an image according to the input image tiling scheme and a user-defined available RAM
Cotb::RAMDrivenStrippedStreamingManager< TImage >	This class computes the divisions needed to stream an image by strips, according to a user-defined available RAM
Cotb::RAMDrivenTiledStreamingManager< TImage >	This class computes the divisions needed to stream an image in square tiles, according to a user-defined available RAM
Cotb::TileDimensionTiledStreamingManager< TImage >	This class computes the divisions needed to stream an image in square tiles, driven by a user-defined tile dimension
Cotb::TestHelper	Helper class to perform the baseline comparisons during the tests
Cotb::VectorDataIOFactory	Create instances of VectorDataIO objects using an object factory
Cotb::WorldFile	Handles the world file that associates geographic information to png, jpg
►Cotb::Wrapper::Application	This class represent an application TODO
►Cotb::Wrapper::CompositeApplication	This class is a base class for composite applications
Cotb::Wrapper::TrainImagesBase	Base class for the TrainImagesClassifier
►Cotb::Wrapper::LearningApplicationBase< TInputValue, TOutputValue >	LearningApplicationBase is the base class for application that use machine learning model
Cotb::Wrapper::TrainVectorBase< TInputValue, TOutputValue >
Cotb::Wrapper::TrainDimensionalityReductionApplicationBase< TInputValue, TOutputValue >
Cotb::Wrapper::VectorPrediction< RegressionMode >
Cotb::Wrapper::ApplicationRegistry
Cotb::Wrapper::CommandLineLauncher	This class check the validity of a command line application
Cotb::Wrapper::CommandLineParser	This class check the validity of a command line application
Cotb::Wrapper::DocExampleStructure	This class is a structure that gathered the necessary element to generate an example (for CommandLine, python ...). User has to set the application name, the binary path and a list of key/value couple
►Cotb::Wrapper::Parameter	This class represent a parameter for the wrapper framework This class is a high level class representing a parameter for the wrapper framework. It should be subclassed to represent different kinds of parameters
►Cotb::Wrapper::NumericalParameter< double >
Cotb::Wrapper::DoubleParameter
►Cotb::Wrapper::NumericalParameter< float >
Cotb::Wrapper::FloatParameter
►Cotb::Wrapper::NumericalParameter< int >
►Cotb::Wrapper::IntParameter
Cotb::Wrapper::RadiusParameter
►Cotb::Wrapper::NumericalParameter< unsigned int >
Cotb::Wrapper::RAMParameter
►Cotb::Wrapper::AbstractParameterList	This class is a base class for list-type parameters
►Cotb::Wrapper::ParameterList< InputImageParameter >
Cotb::Wrapper::InputImageListParameter	This class represents a list of InputImage parameter
►Cotb::Wrapper::ParameterList< StringParameter >
Cotb::Wrapper::InputFilenameListParameter	This class represents a list of InputFilename parameter
Cotb::Wrapper::StringListParameter	This class represent a list of string parameter for the wrapper framework
►Cotb::Wrapper::ParameterList< InputVectorDataParameter >
Cotb::Wrapper::InputVectorDataListParameter	This class represents a list of VectorData parameter
Cotb::Wrapper::ParameterList< T >	This class represents a InputImage parameter
Cotb::Wrapper::BoolParameter	This class represent a boolean parameter for the wrapper framework
Cotb::Wrapper::ChoiceParameter	This class represent a multiple choice parameter for the wrapper framework
Cotb::Wrapper::DirectoryParameter	This class represent a string parameter for the wrapper framework
Cotb::Wrapper::InputFilenameParameter	This class represent a string parameter for the wrapper framework
Cotb::Wrapper::InputImageParameter	This class represents a InputImage parameter
Cotb::Wrapper::InputVectorDataParameter	This class represents a InputVectorData parameter
►Cotb::Wrapper::ListViewParameter	This class represent a ListWidget parameter for the wrapper framework
Cotb::Wrapper::BandParameter	This class represents a band parameter selected from a raster file for the wrapper framework
Cotb::Wrapper::FieldParameter	This class represents a field parameter selected from a vector file for the wrapper framework
Cotb::Wrapper::NumericalParameter< T >	This class represents a numerical parameter
Cotb::Wrapper::OutputFilenameParameter	This class represent a string parameter for the wrapper framework
Cotb::Wrapper::OutputImageParameter	This class represents a OutputImage parameter
Cotb::Wrapper::OutputVectorDataParameter	This class represents a OutputVectorData parameter
Cotb::Wrapper::ParameterGroup
Cotb::Wrapper::ProxyParameter	Parameter class acting as a proxy to a different parameter
Cotb::Wrapper::StringParameter	This class represent a string parameter for the wrapper framework
►Citk::ObjectFactoryBase
Cotb::AutoencoderModelFactory< TInputValue, TTargetValue, NeuronType >
Cotb::BoostMachineLearningModelFactory< TInputValue, TTargetValue >	Create an instance of SVMMachineLearningModel through the object factory
Cotb::CosmoImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::DecisionTreeMachineLearningModelFactory< TInputValue, TTargetValue >	Creation d'un instance d'un object SVMMachineLearningModel utilisant les object factory
Cotb::DefaultImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory. This class only provides the method of the virtual pure class ImageMetadataInterfaceBase and throw exception for virtual method
Cotb::FormosatImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::GDALImageIOFactory	Create an instance of GDALImageIO through the object factory
Cotb::IkonosImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::KNearestNeighborsMachineLearningModelFactory< TInputValue, TTargetValue >	Create an instance of KNearestNeighborsMachineLearningModel through the object factory
Cotb::LibSVMMachineLearningModelFactory< TInputValue, TTargetValue >	Creation of an instance of an object SVMMachineLearningModel using the objects factory
Cotb::NeuralNetworkMachineLearningModelFactory< TInputValue, TTargetValue >	Create an instance of SVMMachineLearningModel through the object factory
Cotb::NormalBayesMachineLearningModelFactory< TInputValue, TTargetValue >	Creation of an instance of object SVMMachineLearningModel using the objects factory
Cotb::OGRVectorDataIOFactory	Create an instance of an OGRVectorDataIOFactory
Cotb::OpticalDefaultImageMetadataInterfaceFactory	Creating an instance of a OpticalImageMetadataInterface object using object factory. This class only provides the method of the virtual pure class OpticalImageMetadataInterface and throw exception for virtual method
Cotb::PCAModelFactory< TInputValue, TTargetValue >
Cotb::PleiadesImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::QuickBirdImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::Radarsat2ImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::RandomForestsMachineLearningModelFactory< TInputValue, TTargetValue >	Creation of an instance of a RandomForestsMachineLearningModel object using the object factory
Cotb::SOMModelFactory< TInputValue, TTargetValue, MapDimension >
Cotb::SVMMachineLearningModelFactory< TInputValue, TTargetValue >	Creation d'un instance d'un object SVMMachineLearningModel utilisant les object factory
Cotb::SarDefaultImageMetadataInterfaceFactory	Creating an instance of a SarImageMetadataInterface object using object factory. This class only provides the method of the virtual pure class SarImageMetadataInterface and throw exception for virtual method
Cotb::Sentinel1ImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::SharkKMeansMachineLearningModelFactory< TInputValue, TTargetValue >	Creation of an instance of a SharkKMeansMachineLearningModel object using the object factory
Cotb::SharkRandomForestsMachineLearningModelFactory< TInputValue, TTargetValue >	Creation of an instance of a SharkRandomForestsMachineLearningModel object using the object factory
Cotb::Spot6ImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::SpotImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::TerraSarXSarImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
Cotb::WorldView2ImageMetadataInterfaceFactory	Creating an instance of a ImageMetadataInterface object using object factory
►Cotb::Wrapper::ApplicationFactoryBase
Cotb::Wrapper::ApplicationFactory< TApplication >
Cotb::Functor::OffsetLexicographicCompare< VOffsetDimension >	Order Offset instances lexicographically
Cotb::internal::OGRCoordinateTransformationDeleter
Cotb::internal::OGRSpatialReferenceDeleter
Cotb::Functor::MultiScaleConvexOrConcaveDecisionRule_tags::opening_profile_characteristics
Cotb::OGRExtendedFilenameToOptions::OpenOptionType
Cotb::functor_filter_details::OperProxy< Oper >
Cotb::functor_filter_details::OperProxy< Out(*)(In...)>
Cotb::functor_filter_details::OperProxy< Out(C::*)(In...) const >
Cotb::functor_filter_details::OperProxy< Out(C::*)(In...)>
Cotb::functor_filter_details::OperProxy< void(*)(Out &, In...)>
Cotb::functor_filter_details::OperProxy< void(C::*)(Out &, In...) const >
Cotb::functor_filter_details::OperProxy< void(C::*)(Out &, In...)>
Cotb::ExtendedFilenameToReaderOptions::OptionType
Cotb::ExtendedFilenameToWriterOptions::OptionType
Cotb::Orbit	This structure is used to handle orbit information
Cotb::Functor::OrientationFunctor< TInputPixel, TOutputPixel >	This functor computes the orientation of a cavariant vector Orientation values lies between 0 and 2*Pi
CotbBarnesDecompFunctor	Evaluate the Huynen decomposition from the reciprocal Sinclair matrix image
CotbEnvelopeSavitzkyGolayInterpolationFunctor	: This class implements a Savitzky-Golay interpolation fitting the upper or lower envelope of the series being interpolated
CotbHAlphaFunctor	Evaluate the H-Alpha parameters from the reciprocal coherency matrix image
CotbMDMDNMFImageFilter	This filter implements unmixing based non negative matrix factorization (NMF) which finds simultaneously the end members and abundances matrix which product is the closer to the observed data, based on the following works: K. S. F.J. Theis and T. Tanaka, First results on uniqueness of sparse non-negative matrix factorisation. M. G. A. Huck and J. Blanc-Talon, IEEE TGRS, vol. 48, no. 6, pp. 2590-2602, 2010. A. Huck and M. Guillaume, in WHISPERS, 2010, Grenoble
CotbSavitzkyGolayInterpolationFunctor	: This functor implements a local polynomial regression (of degree k) on a series of values (of at least k+1 points which are treated as being equally spaced in the series) to determine the smoothed value for each point
Cotb::Functor::OutcoreFunctor< TInput, TOutput >
Cotb::ImageToGenericRSOutputParameters< TImage >::OutputImageExtentType
►Cstd::pair
Cotb::ExtendedFilenameHelper::GenericBandRange
Cotb::PatternSampler::Parameter
Cotb::PeriodicSampler::Parameter
Cotb::RandomSampler::Parameter
Cotb::Wrapper::ParameterKey
Cotb::part_iterator< Splitter >
Cotb::part_range< Splitter >
Cotb::PathLengthFunctor< TInput1 >	Select paths according to their length
Cotb::PathMeanDistanceFunctor< TInput1 >	Functor to select path according to the average distance between points
►Citk::PathSource
►Cotb::ImageToPathFilter< TInputImage, TOutputPath >	Base class for filters taking an image as input, and producing an output of type Path
Cotb::ImageToEdgePathFilter< TInputImage, TOutputPath >	This filter compute the closed edge path of a labelled object in an image (for example coming from a segmentation filter). Its output is a Path
►Citk::PDEDeformableRegistrationFilter
Cotb::NCCRegistrationFilter< TFixedImage, TMovingImage, TDisplacementField >	Deformably register two images using the PDEs and NCC
►Citk::PDEDeformableRegistrationFunction
Cotb::NCCRegistrationFunction< TFixedImage, TMovingImage, TDisplacementField >
CPersistentStreamingLabelImageToOGRDataFilter	This filter is a framework for large scale segmentation. For a detailed description
Cotb::Functor::LevelingFunctor_tags::pixel
Cotb::internals::PixelComponentIterator< TPixel, ConstOrMutable, Dispatch >
Cotb::internals::PixelComponentIterator< ConstMut_IntPixelType, ConstOrMutable >
Cotb::internals::PixelComponentIterator< TPixel, ConstOrMutable, typename std::enable_if_t< boost::is_complex< std::decay_t< TPixel > >::value > >
Cotb::internals::PixelComponentIterator< TPixel, ConstOrMutable, typename std::enable_if_t< mpl::is_array_v< std::decay_t< TPixel > > > >
Cotb::internals::PixelComponentIterator< TPixel, ConstOrMutable, typename std::enable_if_t< std::is_arithmetic< TPixel >::value > >
Cotb::internals::ZipIterator< TImageIterator, ConstOrMutable >::PixelListProxy
Cotb::PixelRange_t< TPixel >
Cotb::PixelTypeDeduction< T >	Helper struct to derive PixelType from template parameter
Cotb::PixelTypeDeduction< itk::ConstNeighborhoodIterator< Image< T > > >	Partial specialisation for itk::ConstNeighborhoodIterator<Image<T>>
Cotb::PixelTypeDeduction< itk::ConstNeighborhoodIterator< VectorImage< T > > >	Partial specialisation for itk::ConstNeighborhoodIterator<VectorImage<T>>
►Citk::PointSetToImageFilter
Cotb::PointSetToDensityImageFilter< TInputPointSet, TOutputImage, TDensityFunction >	Draw the density of a point set on an image
Cotb::Functor::PolarimetricSynthesisFunctor< TInput1, TInput2, TInput3, TInput4, TOutput >	Calculate the polarimetric synthesis
Cotb::Functor::PolarimetricSynthesisFunctor< typename TInputImage::InternalPixelType, typename TInputImage::InternalPixelType, typename TInputImage::InternalPixelType, typename TInputImage::InternalPixelType, typename TOutputImage::PixelType >
Cotb::PolygonCompacityFunctor< TInput1 >	Select polygons according to their compacity
►Cotb::PolyLineImageConstIterator< TImage, TPath >	Uses the bresenham algorithm to iterate over a polyline on an image (const version)
Cotb::PolyLineImageIterator< TImage, TPath >	Uses the bresenham algorithm to iterate over a polyline on an image
►Citk::PolyLineParametricPath
►Cotb::PolyLineParametricPathWithValue< double, 2 >
Cotb::Polygon< TValue >	This class represent a 2D polygon
Cotb::PolyLineParametricPathWithValue< TValue, VDimension >	This class implement a PolyLineParametricPath for which a value can be set. The value is stored in the itk::MetaDataDictionary. The precision of the value can be set
Cotb::PolynomialTimeSeries< TDegree, TCoefPrecision >
►Citk::ProcessObject
Cotb::ImageFileWriter< TImage >
►Cotb::ImageListSource< TImage >
►Cotb::ImageSeriesFileReaderBase< TImage, TImage >
Cotb::ImageSeriesFileReader< TImage, TInternalImage >	Reader class dedicated to image series reading
►Cotb::ImageToImageListFilter< TImage, TImage >
Cotb::GeodesicMorphologyIterativeDecompositionImageFilter< TImage, TStructuringElement >	This class recursively apply geodesic decomposition
Cotb::ImageSeriesFileReaderBase< TImage, TInternalImage >
►Cotb::LabelMapSource< TLabelMap >
Cotb::SpatialisationFilter< TLabelMap >	Create a label map from objects description
Cotb::VectorDataToLabelMapFilter< TVectorData, TLabelMap >	Convert a vector data and produce a collection of label objects for each node
Cotb::VectorDataToLabelMapWithAttributesFilter< TVectorData, TLabelMap >	Converts a vector data into a LabelMap
►Cotb::LabelMapToSampleListFilter< TInputLabelMap, TOutputSampleList, Functor::AttributesMapMeasurementFunctor< typename TInputLabelMap::LabelObjectType, typename TOutputSampleList::MeasurementVectorType > >
Cotb::LabelMapWithClassLabelToLabeledSampleListFilter< TInputLabelMap, TOutputSampleList, TOutputTrainingSampleList, TMeasurementFunctor >	This class converts a LabelObjectMap with some class labeled objects to a SampleList and a TrainingSampleList suitable for supervised learning, and compatible with otb::SVMSampleListModelEstimator
►Cotb::ObjectListSource< ObjectList< TPath > >
►Cotb::ObjectListToObjectListFilter< ObjectList< TPath >, ObjectList< TPath > >
►Cotb::PathListToPathListFilter< TPath >	Base class for filter taking a PathList as input a returning a PathList
Cotb::ImageFittingPolygonListFilter< TPath, TImage >	Slightly deform polygon to reach higher energy from the image
►Cotb::ObjectListSource< ObjectList< Landmark< TPointSet::PointType, TPointSet::PixelType, double > > >
Cotb::KeyPointSetsMatchingFilter< TPointSet, TDistance >	This class matches two point sets according to their associated data
►Cotb::ObjectListSource< ObjectList< TOutputPath > >
►Cotb::PathListSource< TOutputPath >	Base class for filters with a PathList output type
►Cotb::ImageToPathListFilter< TInputImage, TOutputPath >	Base class used to implement filters that have a image as input and a paths list as output
Cotb::RegionImageToRectangularPathListFilter< TInputImage, TOutputPath >	Base class used to implement filter to model regions by rectangles
►Cotb::PersistentFilterStreamingDecorator< PersistentMatrixTransposeMatrixImageFilter< TInputImage1, TInputImage2 > >
Cotb::StreamingMatrixTransposeMatrixImageFilter< TInputImage1, TInputImage2 >	This class streams the whole input image through the PersistentMatrixTransposeMatrixImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentStreamingStatisticsMapFromLabelImageFilter< TInputVectorImage, TLabelImage > >
Cotb::StreamingStatisticsMapFromLabelImageFilter< TInputVectorImage, TLabelImage >	Computes mean radiometric value for each label of a label image, based on a support VectorImage
►Cotb::PersistentFilterStreamingDecorator< PersistentShrinkImageFilter< TInputImage, TInputImage > >
Cotb::StreamingShrinkImageFilter< TInputImage, TOutputImage >	Generates a quicklook of the input image
►Cotb::PersistentFilterStreamingDecorator< PersistentInnerProductVectorImageFilter< TInputImage > >
Cotb::StreamingInnerProductVectorImageFilter< TInputImage >	This class streams the whole input image through the PersistentStatisticsImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentHistogramVectorImageFilter< TInputImage > >
Cotb::StreamingHistogramVectorImageFilter< TInputImage >	This class streams the whole input image through the PersistentHistogramVectorImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentOGRDataToSamplePositionFilter< TInputImage, otb::Image< unsigned char >, otb::PeriodicSampler > >
Cotb::OGRDataToSamplePositionFilter< TInputImage, TMaskImage, TSampler >	Extracts sample position from an image using a persistent filter
►Cotb::PersistentFilterStreamingDecorator< PersistentStreamingStatisticsVectorImageFilter< TInputImage, typename itk::NumericTraits< typename TInputImage::InternalPixelType >::RealType > >
Cotb::StreamingStatisticsVectorImageFilter< TInputImage, TPrecision >	This class streams the whole input image through the PersistentStatisticsImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentMinMaxVectorImageFilter< TInputImage > >
Cotb::StreamingMinMaxVectorImageFilter< TInputImage >	This class streams the whole input image through the PersistentMinMaxVectorImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentOGRDataToClassStatisticsFilter< TInputImage, TMaskImage > >
Cotb::OGRDataToClassStatisticsFilter< TInputImage, TMaskImage >	Computes class statistics based on vectors using a persistent filter
►Cotb::PersistentFilterStreamingDecorator< PersistentStatisticsMosaicFilter< TInputImage, TOutputImage, TInternalValueType > >
Cotb::StreamingStatisticsMosaicFilter< TInputImage, TOutputImage, TInternalValueType >	This class streams the whole input image through the PersistentStatisticsMosaicFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentMinMaxImageFilter< TInputImage > >
Cotb::StreamingMinMaxImageFilter< TInputImage >	This class streams the whole input image through the PersistentMinMaxImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentVectorImageToMatrixFilter< TInputImage > >
Cotb::VectorImageToMatrixImageFilter< TInputImage >	This class streams the whole input image through the PersistentStatisticsImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentImageToOGRLayerSegmentationFilter< TImageType, TSegmentationFilter > >
Cotb::StreamingImageToOGRLayerSegmentationFilter< TImageType, TSegmentationFilter >	This filter is a framework for large scale segmentation. It is a persistent filter that process the input image tile by tile. This filter is templated over the segmentation filter. This later is used to segment each tile of the input image. Each segmentation result (for each tile) is then vectorized using LabelImageToOGRDataSourceFilter (based on GDALPolygonize()). The output OGRDataSource of the LabelImageToOGRDataSourceFilter is a "memory" DataSource (ie all features of a tile are kept in memory). From here some optional processing can be done, depending on input parameters :
►Cotb::PersistentFilterStreamingDecorator< PersistentStatisticsImageFilter< TInputImage > >
Cotb::StreamingStatisticsImageFilter< TInputImage >	This class streams the whole input image through the PersistentStatisticsImageFilter
►Cotb::PersistentFilterStreamingDecorator< PersistentImageSampleExtractorFilter< TInputImage > >
Cotb::ImageSampleExtractorFilter< TInputImage >	Extract sample values from an image into an OGRDataSource using a persistent filter
►Cotb::PersistentFilterStreamingDecorator< PersistentCompareImageFilter< TInputImage > >
Cotb::StreamingCompareImageFilter< TInputImage >	This class streams the whole input image through the PersistentCompareImageFilter
►Cotb::PointSetSource< TPointSet >
Cotb::DisparityMapEstimationMethod< TFixedImage, TMovingImage, TPointSet >	This class performs an estimation of the local displacement modelled by a given transform between the fixed and the moving image, at each point of the given point set
►Cotb::PointSetSource< itk::PointSet< typename TInputImage::PixelType, 2 > >
►Cotb::ImageToPointSetFilter< TInputImage, itk::PointSet< typename TInputImage::PixelType, 2 > >
Cotb::HarrisImageToPointSetFilter< TInputImage, TOutputPointSet >	TODO
Cotb::ThresholdImageToPointSetFilter< TInputImage, TOutputPointSet >	Produce a PointSet according to filtering conditions
Cotb::VectorDataFileWriter< otb::VectorData >
►Cotb::VectorDataSource< otb::VectorData<> >
►Cotb::OSMDataToVectorDataGenerator	Request OSM Server using the OSM API 0.6 to get the xml file storing the vector elements available
Cotb::ImageToOSMVectorDataGenerator< TImage >	Helper class to compute the extent of the input image and use it to fill the bbox for the OSM request
►Cotb::VectorDataSource< TVectorData >
►Cotb::VectorDataToVectorDataFilter< TVectorData, TVectorData >
Cotb::VectorDataExtractROI< TVectorData >	Extract a subset of a Vector Data based on location
Cotb::VectorDataToRightAngleVectorDataFilter< TVectorData >	Right angle detector
Cotb::VectorDataToSpecificDescriptionFilterBase< TVectorData >	Base class for VectorDataToSpecificDescriptionFilters
Cotb::ConcatenateVectorDataFilter< TVectorData >	Produces a VectorData from the concatenation of several input vectordatas
Cotb::LabelMapToVectorDataFilter< TLabelMap, TVectorData, TFieldsFunctor >	This class vectorizes a LabelObject to a VectorData
Cotb::VectorDataToRandomLineGenerator< TVectorData >	Produces a VectorData Containing Random Lines
►Cotb::VectorDataSource< otb::VectorData< double > >
Cotb::LabelImageToVectorDataFilter< TInputImage, TPrecision >	This class uses GDALPolygonize method to transform a Label image into a VectorData. An optional input mask can be used to exclude pixels from vectorization process. All pixels with a value of 0 in the input mask image will not be suitable for vectorization
Cotb::LineSegmentDetector< TInputImage, TPrecision >	This class implement a fast line detector with false detection control using the a contrario method
Cotb::AeronetFileReader	This class reads a Aeronet data from an Aeronet file
Cotb::ConfusionMatrixToMassOfBelief< TConfusionMatrix, TLabel >	This class converts a confusion matrix into masses of belief for each label
Cotb::GDALOverviewsBuilder
Cotb::GeometriesSource
Cotb::ImageFileWriter< TInputImage >	Writes image data to a single file with streaming process
►Cotb::ImageListSource< TOutputImage >	Base class for all the filters producing an otbImageList
►Cotb::ImageListToImageListFilter< TInputImageList::ImageType, TOutputImageList::ImageType >
Cotb::ImageListToImageListApplyFilter< TInputImageList, TOutputImageList, TFilter >	This filter applies the filter given as template to the input image list
►Cotb::ImageSeriesFileReaderBase< VectorImage< TPixel, 2 >, VectorImage< TInternalPixel, 2 > >
Cotb::ImageSeriesFileReader< VectorImage< TPixel, 2 >, VectorImage< TInternalPixel, 2 > >
►Cotb::ImageSeriesFileReaderBase< Image< TPixel, 2 >, Image< TInternalPixel, 2 > >
Cotb::ImageSeriesFileReader< Image< TPixel, 2 >, Image< TInternalPixel, 2 > >
►Cotb::ImageSeriesFileReaderBase< Image< TPixel, 2 >, VectorImage< TInternalPixel, 2 > >
Cotb::ImageSeriesFileReader< Image< TPixel, 2 >, VectorImage< TInternalPixel, 2 > >
►Cotb::ImageToImageListFilter< TImage, TImageList::ImageType >
Cotb::WaveletsSynopsisImageToWaveletsBandsListFilter< TImage, TImageList >	This class convert the standard wavelets view to a list of bands
►Cotb::ImageToImageListFilter< TVectorImageType, TImageList::ImageType >
Cotb::VectorImageToImageListFilter< TVectorImageType, TImageList >	This class aims at converting a multi-band image to a list of scalar images
►Cotb::ImageListToImageListFilter< TInputImage, TOutputImage >	Base class for all the filters taking an image list as input to produce an image list
Cotb::ProfileToProfileDerivativeFilter< TInputImage, TOutputImage >	This filter computes the derivative of a given profile
►Cotb::ImageToImageListFilter< TInputImage, TOutputImage >	Base class for all the filters taking an image input to produce an image list
►Cotb::ImageToProfileFilter< TInputImage, TOutputImage, itk::OpeningByReconstructionImageFilter< TInputImage, TOutputImage, TStructuringElement >, unsigned int >
Cotb::MorphologicalOpeningProfileFilter< TInputImage, TOutputImage, TStructuringElement >	This filter compute the morphological opening profile
►Cotb::ImageToProfileFilter< TInputImage, TOutputImage, itk::ClosingByReconstructionImageFilter< TInputImage, TOutputImage, TStructuringElement >, unsigned int >
Cotb::MorphologicalClosingProfileFilter< TInputImage, TOutputImage, TStructuringElement >	This filter compute the morphological closing profile
Cotb::AngularProjectionSetImageFilter< TInputImage, TOutputImage, TAngleList, TPrecision >	Performs spherical transformation in ND space from a set of angle values
Cotb::ImageToProfileFilter< TInputImage, TOutputImage, TFilter, TParameter >	Base class to produce a profile of the response of a given filter for a range of parameter
Cotb::SparseUnmixingImageFilter< TInputImage, TOutputImage, VNbInputImage, TPrecision, TMotherWaveletOperator >	This class detects linear dependencies from N wavelet decompositions
Cotb::WaveletPacketTransform< TInputImage, TOutputImage, TFilter, Wavelet::FORWARD, TCost >
Cotb::WaveletTransform< TInputImage, TOutputImage, TFilter, Wavelet::FORWARD >
Cotb::JointMassOfBeliefFilter< TMassFunction >	Performs Dempster-Shafer combination of n masses function
Cotb::LabelImageSmallRegionMergingFilter< TInputLabelImage >
Cotb::LabelImageToOGRDataSourceFilter< TInputImage >
Cotb::LabelMapSource< TOutputLabelMap >	Base class for filter that output LabelMap
Cotb::LabelMapToSampleListFilter< TInputLabelMap, TOutputSampleList, TMeasurementFunctor >	This class converts a LabelObjectMap to a SampleList for learning and classification
►Cotb::LabelToSimulationParametersBase< TLabel >	Base class for all classes that take a label and outputs two set of parameters for two steps (step1, step2)
Cotb::LabelToProSailParameters< TLabel >	Take a label corresponding to a spectrum type for vegetation and outputs the ProSail parameters needed to get a spectrum of that type
Cotb::ListSampleGenerator< TImage, TVectorData >	Produces a ListSample from a VectorImage and a VectorData
Cotb::ListSampleToHistogramListGenerator< TListSample, THistogramMeasurement, TFrequencyContainer >	Generates a list of 1D Histograms from a ListSample This class is similar to ListSampleToVariableDimensionHistogramGenerator, except from the fact that it computes one histogram per channel instead of a single joint-histogram. The output is a Histogram list (
Cotb::ListSampleToVariableDimensionHistogramGenerator< TListSample, THistogramMeasurement, TFrequencyContainer >	Generates a VariableDimensionHistogram from a ListSample
Cotb::MapFileProductWriter< TInputImage >	This class produces Map file product ie a file .map, the tiles to draw in a mapserver, and finally a shapefile which describe the tiles and where to find them on the disk
Cotb::MultiImageFileWriter	Streams a pipeline with multiple outputs. It writes each output to a file. Inputs are connected to the writer using the AddInputImage method. The type of streaming can be chosen. Each output may have a different size. When the user gives a number of lines per strip or a tile size, the value is interpreted on the first input to deduce the number of streams. This number of streams is then used to split the other inputs
Cotb::OGRLayerStreamStitchingFilter< TInputImage >	This filter fusion the geometries in a layer (OGRLayer) along streaming lines. It is a in-line filter which means that the result of the fusion overwrites the input layer. The strategy for merging polygons is quite simple. A polygon P1 is merge with a polygon P2 if:
►Cotb::ObjectListSource< TOutputList >	Base class for all process objects that output ObjectList data
►Cotb::ObjectListToObjectListFilter< TInputList, TOutputList >	Base class for filters that take an ObjectList as input and produce an ObjectList as output
Cotb::UnaryFunctorObjectListBooleanFilter< TInputList, TOutputList, TFunction >	Filter an ObjectList and keep elements according to the functor value
Cotb::UnaryFunctorObjectListFilter< TInputList, TOutputList, TFunction >	Process each element in the ObjectList with the functor
Cotb::PathListToHistogramGenerator< TPath, TFunction >	This class generates an histogram from a list of path
Cotb::PersistentFilterStreamingDecorator< TFilter >	This filter link a persistent filter with a StreamingImageVirtualWriter
►Cotb::PointSetSource< TOutputPointSet >	Base class for all process objects that output point set data
►Cotb::ImageToPointSetFilter< TInputImage, TOutputPointSet >	Base class to output PointSet data with image data as input
Cotb::ImageToSIFTKeyPointSetFilter< TInputImage, TOutputPointSet >	This class extracts key points from an input image, trough a pyramidal decomposition
Cotb::ImageToSURFKeyPointSetFilter< TInputImage, TOutputPointSet >	This class extracts key points from an image through a pyramidal gaussian based decomposition
Cotb::SiftFastImageFilter< TInputImage, TOutputPointSet >	This class extracts key points from an input image through a pyramidal decomposition
►Cotb::PointSetToPointSetFilter< TInputPointSet, TOutputPointSet >	Base class to process PointSet data
Cotb::PointSetExtractROI< TInputPointSet, TOutputPointSet >	Extract a part of the points specified by a region
Cotb::TransformPointSetFilter< TInputPointSet, TOutputPointSet, TTransform >	TransformPointSetFilter applies a transform to all the points of a PointSet
Cotb::RandomPointSetSource< TOutputPointSet >	This class generate a random point set
Cotb::RGBAPixelConverter< TInternalInputPixelType, TOutputPixelType >	Convert an itk::RGBApixel<InternalType> into another pixel type
Cotb::RGBAPixelConverter< TInternalInputPixelType, itk::RGBAPixel< TInternalOutputPixelType > >
Cotb::RGBAPixelConverter< TInternalInputPixelType, itk::RGBPixel< TInternalOutputPixelType > >
Cotb::SOMClassifier< TSample, TSOMMap, TLabel >	This class implements a SOM-Based classifier
Cotb::SampleAugmentationFilter	Filter to generate synthetic samples from existing ones
Cotb::ScalarBufferToImageFileWriter< TBufferType, TOutputPixelType >	Record an image stored in a buffer
►Cotb::SimulationStep1Base	Base class for all method that simulate the Reflectance and Transmittance of an object. (ex: Prospect)
Cotb::ProspectModel	This class implements the Prospect Model (see http://teledetection.ipgp.jussieu.fr/prosail/),
►Cotb::SimulationStep2Base	Base class for all methods that generate spectrum of an object using its reflectance and transmittance
Cotb::SailModel	This class implements the SAIL model (see http://teledetection.ipgp.jussieu.fr/prosail/)
Cotb::SpectralSensitivityReader	Read a file that contains spectral sensitivity
►Cotb::Statistics::ListSampleSource< TInputSampleList, TOutputSampleList >	This class is a base class for filters using ListSample as input and returning ListSample
►Cotb::Statistics::ListSampleToListSampleFilter< TSampleList, TSampleList >
Cotb::Statistics::ConcatenateSampleListFilter< TSampleList >	This class concatenates several sample list into a single one
►Cotb::Statistics::ListSampleToListSampleFilter< TInputSampleList, TInputSampleList >
Cotb::Statistics::GaussianAdditiveNoiseSampleListFilter< TInputSampleList, TOutputSampleList >	This class generate a noised version of the input sample list
Cotb::Statistics::ListSampleToBalancedListSampleFilter< TInputSampleList, TLabelSampleList, TOutputSampleList >	This class generate a balanced ListSample in order to have fair distribution of learning samples
Cotb::Statistics::ShiftScaleSampleListFilter< TInputSampleList, TOutputSampleList >	This class generate a shifted and scaled version of the input sample list
Cotb::Statistics::ListSampleToListSampleFilter< TInputSampleList, TOutputSampleList >	This class is a base class for filters using ListSample as input and returning ListSample
Cotb::VariableLengthVectorConverter< TInputType, TPrecisionType >	Convert any data container type into a VariableLengthVector
Cotb::VariableLengthVectorConverter< itk::FixedArray< TInternalInputType, VArrayDimension >, TPrecisionType >
Cotb::VariableLengthVectorConverter< itk::SmartPointer< itk::Statistics::Histogram< TPixel > >, TPrecisionType >
Cotb::VariableLengthVectorConverter< itk::VariableLengthVector< TInternalInputType >, TPrecisionType >
Cotb::VariableLengthVectorConverter< std::vector< std::vector< TInternalInputType > >, TPrecisionType >
Cotb::VariableLengthVectorConverter< std::vector< std::vector< std::complex< TInternalInputType > > >, TPrecisionType >
Cotb::VectorDataFileWriter< TInputVectorData >	This class writes vector data file format (shapefile and KML)
►Cotb::VectorDataSource< TOutputVectorData >	Filter hierarchy for generating VectorData
►Cotb::VectorDataToVectorDataFilter< TInputVectorData, TInputVectorData >
Cotb::VectorDataIntoImageProjectionFilter< TInputVectorData, TInputImage >	Reproject vector data into the coordinate system of an image
Cotb::ImageToEnvelopeVectorDataFilter< TInputImage, TOutputVectorData >	Build a vector data containing the polygon of the image envelope
Cotb::VectorDataFileReader< TOutputVectorData >	Data source that reads vector data from a single file
►Cotb::VectorDataToVectorDataFilter< TInputVectorData, TOutputVectorData >	Base class for filters that take an VectorData as input and produce an VectorData as output
Cotb::VectorDataAdapter< TInputVectorData, TOutputVectorData >	Helper class to convert the vector data to generic type
Cotb::VectorDataProjectionFilter< TInputVectorData, TOutputVectorData >	Reproject vector data in a different coordinate system
Cotb::VectorDataTransformFilter< TInputVectorData, TOutputVectorData >	Apply a Transform To a VectorData
►CITK_EXPORT itk::ProcessObject
Cotb::SparseWvltToAngleMapperListFilter< TInputImageList, TOutputSampleList, VNbInputImages >	This class select N-uple join-wvlt coeff for sparse unmixing
Cotb::Functor::ProjectiveProjectionFunctor< TInput, TOutput, TPrecision >	Applies a projective projection to a pixel
CProjectiveProjectionImageFilter	Applies a projective projection to each pixel of an image
Cotb::Function::ProlateFunction< TInput, TOutput >	Prolate function give the value of the prolate profile following one of the 2 image dimension
Cotb::ogr::propagate_const< Tin, Tout >	Propagation of const-qualifier
Cotb::ogr::propagate_const< Tin const, Tout >
Cotb::Functor::RadianceToImageImageFunctor< TInput, TOutput >	Subtract beta to the Input and multiply by alpha
Cotb::Functor::RadianceToReflectanceImageFunctor< TInput, TOutput >	Compute reflectance from the radiance value
►Cotb::Functor::RadiometricIndex< TInput, TOutput >	Base class for all radiometric indices
Cotb::Functor::NDVI< typename TReduceSpectralResponse::ValuePrecisionType, typename TReduceSpectralResponse::ValuePrecisionType >
Cotb::Functor::ARVI< TInput, TOutput >	This functor computes the Atmospherically Resistant Vegetation Index (ARVI)
Cotb::Functor::AVI< TInput, TOutput >	This functor computes the Angular Vegetation Index (AVI)
Cotb::Functor::BI< TInput, TOutput >	This functor computes the Brilliance Index (BI)
Cotb::Functor::BI2< TInput, TOutput >	This functor computes the Brilliance Index (BI2)
Cotb::Functor::CI< TInput, TOutput >	This functor computes the Color Index (IC)
Cotb::Functor::EVI< TInput, TOutput >	This functor computes the Enhanced Vegetation Index (EVI)
Cotb::Functor::GEMI< TInput, TOutput >	This functor computes the Global Environment Monitoring Index (GEMI)
Cotb::Functor::IPVI< TInput, TOutput >	This functor computes the Infrared Percentage Vegetation Index (IPVI)
Cotb::Functor::ISU< TInput, TOutput >	This functor computes the Index surfaces built (ISU)
Cotb::Functor::LAIFromNDVIFormosat2Functor< TInput, TOutput >	Use red and nir image band to compute LAI image using formula a*(exp(nir-red)/((red+nir)*b)-exp(c*b)); with a = 0.1519 b = 3.9443 c = 0.13 this formula is only valid for Formosat 2 reflectance TOC
Cotb::Functor::LAIFromNDVILogarithmic< TInput, TOutput >	Computes the LAI from NDVI
Cotb::Functor::LAIFromReflectancesLinear< TInput, TOutput >	Computes the LAI from reflectances
Cotb::Functor::MNDWI< TInput, TOutput >	This functor computes the Modified Normalized Difference Water Index (MNDWI)
Cotb::Functor::MSAVI< TInput, TOutput >	This functor computes the Modified Soil Adjusted Vegetation Index (MSAVI)
Cotb::Functor::MSAVI2< TInput, TOutput >	This functor computes the Modified Soil Adjusted Vegetation Index (MSAVI2)
Cotb::Functor::NDTI< TInput, TOutput >	This functor computes the Normalized Difference Turbidity Index (NDTI)
Cotb::Functor::NDVI< TInput, TOutput >	This functor computes the Normalized Difference Vegetation Index (NDVI)
Cotb::Functor::NDWI< TInput, TOutput >	This functor computes the Normalized Difference Water Index (NDWI)
Cotb::Functor::NDWI2< TInput, TOutput >	This functor computes the Normalized Difference Water Index (NDWI2)
Cotb::Functor::PVI< TInput, TOutput >	This functor computes the Perpendicular Vegetation Index (PVI)
Cotb::Functor::RI< TInput, TOutput >	This functor computes the Redness Index (RI)
Cotb::Functor::RVI< TInput, TOutput >	This functor computes the Ratio Vegetation Index (RVI)
Cotb::Functor::SAVI< TInput, TOutput >	This functor computes the Soil Adjusted Vegetation Index (SAVI)
Cotb::Functor::TNDVI< TInput, TOutput >	This functor computes the Transformed NDVI (TNDVI)
Cotb::Functor::TSAVI< TInput, TOutput >	This functor computes the Transformed Soil Adjusted Vegetation Index (TSAVI)
Cotb::Functor::WDVI< TInput, TOutput >	This functor computes the Weighted Difference Vegetation Index (WDVI)
Cotb::Functor::WaterSqrtSpectralAngleFunctor< TInput, TOutput >	This functor uses a spectral angle with a particular reference pixel
Cotb::Functor::RadiometricMomentsFunctor< TNeighIter, TPrecision >
Cotb::Functor::RadiometricMomentsFunctor< itk::ConstNeighborhoodIterator< InputImageType >, ScalarRealType >
Cotb::Functor::RadiometricMomentsFunctor< itk::ConstNeighborhoodIterator< InputImageType >, ScalarType >
Cotb::RadiometryCorrectionParametersToAtmosphericRadiativeTerms	TODO
Cotb::Function::RealAndImaginaryToComplex< TInputImageRealPart, TInputImageImaginaryPart, TOutput >
Cotb::Function::RealToComplex< TInputImageRealPart, TOutput >
Cotb::Functor::ReciprocalBarnesDecompFunctor< TInput, TOutput >
Cotb::Functor::ReciprocalCoherencyToReciprocalMuellerFunctor< TInput, TOutput >
Cotb::Functor::ReciprocalCovarianceToCoherencyDegreeFunctor< TInput, TOutput >	Evaluate the Coherency Degree coefficient from from the MLC image
Cotb::Functor::ReciprocalCovarianceToReciprocalCoherencyFunctor< TInput, TOutput >	Evaluate the Coherency matrix from the Covariance image
Cotb::Functor::ReciprocalHAlphaFunctor< TInput, TOutput >
Cotb::Functor::ReciprocalHuynenDecompFunctor< TInput, TOutput >	Evaluate the Huynen decomposition from the reciprocal Sinclair matrix image
Cotb::Functor::ReciprocalLinearCovarianceToReciprocalCircularCovarianceFunctor< TInput, TOutput >	Compute the reciprocal Covariance circular matrix from the reciprocal Covariance linear matrix. Extract from Antennas for radar and communications Harold Mott p 317
Cotb::Functor::ReciprocalPauliDecompFunctor< TInput, TOutput >	Evaluate the Pauli decomposition from the reciprocal Sinclair matrix image
Cotb::Functor::ReflectanceToImageImageFunctor< TInput, TOutput >	Call the ReflectanceToRadianceFunctor over the input and the RadianceToImageFunctor to this result
Cotb::Functor::ReflectanceToRadianceImageFunctor< TInput, TOutput >	Compute radiance from the reflectance value
Cotb::Functor::ReflectanceToSurfaceReflectanceImageFunctor< TInput, TOutput >	Compute the surface reflectance pixel from a TOA reflectance
►Citk::Region
Cotb::RemoteSensingRegion< double >
Cotb::RemoteSensingRegion< typename VertexType::CoordRepType >
Cotb::RemoteSensingRegion< TType >	An RemoteSensingRegion represents a structured region of data
►Citk::RelabelComponentImageFilter
Cotb::RelabelComponentImageFilter< TInputImage, TOutputImage >	Relabel the components in an image such that consecutive labels are used
Cotb::internal::ReprojectTransformationFunctor
Cotb::RetrieveOperator< T >	Struct to retrieve the operator type
Cotb::ObjectList< TObject >::ReverseConstIterator	ReverseConstIterator of the object list
Cotb::ObjectList< TObject >::ReverseIterator	ReverseIterator of the object list
Cotb::Functor::RGB2LAB< TInput, TOutput >	Base class for converting RGB into LAB color space (Ruderman et al.)
Cotb::LabelImageToLabelMapWithAdjacencyFilter< TInputImage, TOutputImage >::RLE
►Cotb::details::policy::root_layout_mapping< Extents >
Cotb::details::policy::left_< Extents >
Cotb::details::policy::right_< Extents >
Cotb::details::policy::stride_< Extents >
Cotb::Projection::RPCParam	Coefficients for RPC model (quite similar to GDALRPCInfo)
►Ccv::ml::RTrees
Cotb::CvRTreesWrapper	Wrapper for OpenCV Random Trees
►Citk::Statistics::SampleClassifierFilter
Cotb::SEMClassifier< TInputImage, TOutputImage >	This class implements the Stochastic Expectation Maximization algorithm to perform an estimation of a mixture model
Cotb::SVMMarginSampler< TSample, TModel >	Implement one iteration of active learning by margin
Cotb::Wrapper::TrainVectorBase< TInputValue, TOutputValue >::SamplesWithLabel
Cotb::Wrapper::TrainImagesBase::SamplingRates
Cotb::Functor::SarBrightnessFunctor< TInput, TOutput >	Compute the brightness value.
Cotb::SARCalib	SAR calibration LUTs
Cotb::SARParam	SAR sensors parameters
Cotb::SarSensorModel
Cotb::Functor::SavitzkyGolayInterpolationFunctor< Radius, TSeries, TDates, TWeight, Degree >
Cotb::Functor::SavitzkyGolayInterpolationFunctor< Radius, TSeries, TDates, TSeries >
Cgrm::Segmenter< TImage, TNode, TParam >
►Cgrm::Segmenter< TImage, BaatzNode, BaatzParam >
Cgrm::BaatzSegmenter< TImage >
►Cgrm::Segmenter< TImage, FLSNode, FLSParam >
Cgrm::FullLambdaScheduleSegmenter< TImage >
►Cgrm::Segmenter< TImage, SpringNode, SpringParam >
Cgrm::SpringSegmenter< TImage >
Cotb::MetaData::PleiadesUtils::SensorModelCharacteristics
Cotb::Sentinel1AzimuthNoiseStruct
Cotb::Sentinel1CalibrationStruct	Structure holding a calibration vector from Sentinel1 annotation files
Cotb::Functor::SFSTexturesFunctor< TIter, TOutputValue >
CSFSTexturesFunctor	This functor computes textures based on line direction analysis through the central pixel
Cotb::Functor::SFSTexturesFunctor< NeighborhoodIteratorType, OutputImagePixelType >
Cotb::Functor::ShapeAttributesLabelObjectFunctor< TLabelObject, TLabelImage >	Functor to compute shape attributes of one LabelObject
CSharkKMeansMachineLearningModel	Shark version of Random Forests algorithm
CSharkRandomForestsMachineLearningModel	Shark version of Random Forests algorithm
Cotb::Wrapper::TrainVectorBase< TInputValue, TOutputValue >::ShiftScaleParameters
Cotb::Accessor::ShiftScalePixelAccessor< TPixelType, TExternalType >	Apply a shift scale operation to the value
Cotb::PersistentSamplingFilterBase< TInputImage, TMaskImage >::SimpleFieldDefn
Cotb::SimplifyPathFunctor< TInput, TOutput >	This filter performs a simplification of the input path
Cotb::Functor::SinclairToCircularCovarianceMatrixFunctor< TInput1, TInput2, TInput3, TInput4, TOutput >	Construct the fully polarimetric circular covariance matrix with Sinclair matrix information
Cotb::Functor::SinclairToCoherencyMatrixFunctor< TInput1, TInput2, TInput3, TInput4, TOutput >	Construct the fully polarimetric coherency matrix with Sinclair matrix information
Cotb::Functor::SinclairToCovarianceMatrixFunctor< TInput1, TInput2, TInput3, TInput4, TOutput >	Construct the fully polarimetric covariance matrix with Sinclair matrix information
Cotb::Functor::SinclairToMuellerMatrixFunctor< TInput1, TInput2, TInput3, TInput4, TOutput >	Construct Mueller matrix with Sinclair matrix information. Elements of the Mueller matrix are extract from Antennas for radar and communications Harold Mott p 503
Cotb::Functor::SinclairToReciprocalCircularCovarianceMatrixFunctor< TInput1, TInput2, TInput3, TOutput >	Construct the fully reciprocal polarimetric circular covariance matrix with Sinclair matrix information
Cotb::Functor::SinclairToReciprocalCoherencyMatrixFunctor< TInput1, TInput2, TInput3, TOutput >	Construct the reciprocal fully polarimetric coherency matrix with Sinclair matrix information
Cotb::Functor::SinclairToReciprocalCovarianceMatrixFunctor< TInput1, TInput2, TInput3, TOutput >	Construct the reciprocal fully polarimetric covariance matrix with Sinclair matrix information
Cotb::Functor::SingleComplexToVector< TInput, TOutput >
►Citk::SingleValuedCostFunction
Cotb::SVMCrossValidationCostFunction< TModel >	This function returns the cross validation accuracy of a SVM model
►Citk::SingleValuedNonLinearOptimizer
Cotb::ExhaustiveExponentialOptimizer	This optimizer performs an exhaustive search on an exponential scale
►Cotb::MultiImageFileWriter::SinkBase
Cotb::MultiImageFileWriter::Sink< TImage >
Cotb::SIXSTraits	SIXSTraits operations
Cotb::Functor::SobelOperator< TInput, TOutput >	Performs the calculation of Sobel derivation
Cotb::SoilDataBase
Cotb::Functor::SOMbasedImageFilterFunctor< TInput, TOutput, TDistanceMetric, TMap >	This class implements the functor that perform substitution between input image pixels and the corresponding winning neurons of a Kohonen map
Cotb::Functor::SOMLearningBehaviorFunctor	Classical Beta behavior over SOM training phase
Cotb::SatelliteRSR< TPrecision, TValuePrecision >::sort_band
Cotb::SpectralResponse< TPrecision, TValuePrecision >::sort_pair
Cotb::OGRLayerStreamStitchingFilter< TInputImage >::SortFeatureStruct
Cotb::Span< T >
►Citk::SpatialFunction
►Cotb::PointSetFunction< TPointSet, TOutput >	Calculate the density in the neighborhood of a pixel
Cotb::PointSetDensityEpanechnikovFunction< TPointSet, TOutput >	Calculate the density in the neighborhood of a pixel using an Epanechnikov function
Cotb::PointSetDensityFunction< TPointSet, TOutput >	Calculate the density in the neighborhood of a pixel using a simple cut off method
Cotb::PointSetDensityGaussianFunction< TPointSet, TOutput >	Calculate the density in the neighborhood of a pixel using a gaussian function
Cotb::Meanshift::SpatialRangeJointDomainTransform< TInputImage, TOutputJointImage >
Cotb::SpatialReference	This class is a wrapper around OGRSpatialReference
Cotb::Functor::SpectralAngleFunctor< TInput, TOutputValue >	This functor computes the spectral angle according to a reference pixel
Cotb::Functor::SpectralAngleMapperFunctor< TInput, TReference, TOutput >	This functor computes the spectral angle according to a vector of reference pixel
Cotb::Functor::SpectralInformationDivergenceFunctor< TInput, TReference, TOutput >
CGapFilling::SplineGapFillingFunctor< PixelType >
Cotb::splitter_on_delim
Cotb::Spot5Param	Spot5 sensors parameters
Cotb::Spot5SensorModel
Cgrm::SpringParam
Cotb::Functor::SqrtSpectralAngleFunctor< TInput, TOutputValue >	This functor computes the square root of a spectral angle according to a reference pixel
Cotb::Functor::SSDBlockMatching< TInputImage, TOutputMetricImage >	Functor to perform simple SSD block-matching
Cotb::Functor::SSDDivMeanBlockMatching< TInputImage, TOutputMetricImage >	Functor to perform derived SSD block-matching (SSD divided by mean)
Cotb::StandardOutputPrintCallback	Class with printing callback methods using the standard output
Cotb::StatisticsAccumulator< TRealVectorPixelType >
Cotb::Functor::StatisticsAttributesLabelObjectFunctor< TLabelObject, TFeatureImage >	Functor to compute statistics attributes of one LabelObject
CStatisticsMapAccumulator	Holds statistics for each label of a label image
Cotb::Stopwatch	Stopwatch timer
Cotb::MetaData::details::streamable< T >
►Cotb::MetaData::details::streamable< Duration >
Cotb::MetaData::Duration	Represents a duration
►Cotb::MetaData::details::streamable< TimePoint >
Cotb::MetaData::TimePoint	Represents a point in Time
Cotb::StreamingConnectedComponentSegmentationOBIAToVectorDataFilter< TVImage, TLabelImage, TMaskImage, TOutputVectorData >	Performs connected component segmentation on an input image, apply OBIA filtering and output a VectorData, with streaming capabilities
Cotb::StreamingLineSegmentDetector< TImageType >
Cotb::StreamingTraits< TImage >	This class provides internal information for streamable filters
Cotb::StreamingTraits< otb::VectorImage< TPixel, VImageDimension > >
Cotb::string_view
Cotb::ogr::StringListConverter	Helper class to convert a set of standard C++ string into char** as OGR API expects
►Cotb::Wrapper::StringListInterface	This class represents a list of InputFilename parameter
Cotb::Wrapper::AbstractParameterList	This class is a base class for list-type parameters
Cotb::ogr::internal::StringListMemberGetterPtr< FinalReturnType >
Cotb::ogr::internal::StringListMemberSetterPtr< ActualParamType >
Cotb::StringToHTML
Cotb::MetaData::details::substractable_asym< U, V >
►Cotb::MetaData::details::substractable_asym< Duration, TimePoint >
Cotb::MetaData::TimePoint	Represents a point in Time
►Cboost::subtractable
Cotb::MetaData::Duration	Represents a duration
Cotb::MetaData::Duration	Represents a duration
Cotb::System	System operations
Cotb::ogr::internal::TagDispatchMemberContainerSetterPtr< T, ptr_to_function, ActualParamType, Is_contiguous >	Dispatcher function for the Field Setter. The container-field setters from OGR API have a C API. This dispatcher will check whether the parameter container has a contiguous storage. If so it will directly inject the address of the first element of the contiguous container in the OGR C API. If not, the container will be converted into a container with contiguous storage
Cotb::ogr::internal::TagDispatchMemberContainerSetterPtr< T, ptr_to_function, ActualParamType, false >
Cotb::ogr::internal::TagDispatchMemberContainerSetterPtr< T, ptr_to_function, ActualParamType, true >
►Citk::TernaryFunctorImageFilter
Cotb::TernaryFunctorImageFilter< TInputImage1, TInputImage2, TInputImage3, TOutputImage, TFunction >	Implements pixel-wise generic operation on three images
Cotb::Functor::TerraSarBrightnessFunctor< TInput, TOutput >	Compute beta naught coefficient
Cotb::part_iterator< Splitter >::theend
Cotb::PersistentStatisticsMosaicFilter< TInputImage, TOutputImage, TInternalValueType >::ThreadResultsContainer
Cotb::ImageToPointSetFilter< TInputImage, TOutputPointSet >::ThreadStruct
Cotb::ObjectListToObjectListFilter< TInputList, TOutputList >::ThreadStruct
Cotb::UnaryFunctorObjectListBooleanFilter< TInputList, TOutputList, TFunction >::ThreadStruct
Cotb::Functor::TimeSeriesLeastSquareFittingFunctor< TSeriesType, TTimeFunction, TDateType, TWeightType >	Implements a least squares fitting of a time profile
Cotb::Wrapper::TrainImagesBase::TrainFileNamesHandler
►Citk::Transform
►Cotb::Transform< TScalarType, 2, 3 >
►Cotb::SensorTransformBase< TScalarType, NInputDimensions, NOutputDimensions >	Base class for the sensor model projection classes
►Cotb::RPCTransformBase< TScalarType, 3, 2 >
Cotb::RPCForwardTransform< TScalarType, NInputDimensions, NOutputDimensions >	Projection class based on the RPC method
Cotb::RPCInverseTransform< TScalarType, NInputDimensions, NOutputDimensions >	Projection class based on the RPC method
►Cotb::SarTransformBase< TScalarType, 3, 2 >
Cotb::SarForwardTransform< TScalarType, NInputDimensions, NOutputDimensions >	Projection class based on the Sar model
Cotb::SarInverseTransform< TScalarType, NInputDimensions, NOutputDimensions >	Projection class based on the Sar model
►Cotb::Spot5TransformBase< TScalarType, 3, 2 >
Cotb::Spot5ForwardTransform< TScalarType, NInputDimensions, NOutputDimensions >	Projection class based on the Spot5 model
Cotb::Spot5InverseTransform< TScalarType, NInputDimensions, NOutputDimensions >	Projection class based on the Spot5 model
►Cotb::Transform< double, 3, 3 >
Cotb::GeocentricTransform< otb::TransformDirection::FORWARD, double >
Cotb::GeocentricTransform< otb::TransformDirection::INVERSE, double >
Cotb::GeocentricTransform< TDirectionOfMapping, TScalarType >	Convert coordinates from geocentric (X, Y, Z) to geographic (lon, lat, h)
►Cotb::Transform< double, 2, 2 >
Cotb::GenericMapProjection< TDirectionOfMapping, TScalarType, NInputDimensions, NOutputDimensions >	This is the base class for generic map projection transformation
Cotb::GenericRSTransform< TScalarType, NInputDimensions, NOutputDimensions >	This is the class to handle generic remote sensing transform
Cotb::RationalTransform< TScalarType, Dimension >	This class implements a rational transform
Cotb::TileMapTransform< TTransformDirection, TScalarType, NInputDimensions, NOutputDimensions >	To do
►Cotb::Transform< TScalarType, 2, 2 >
Cotb::InverseLogPolarTransform< TScalarType >	This transform is the back transform of the LogPolarTransform
Cotb::LogPolarTransform< TScalarType >	Implement the log-polar coordinate transform
►Cotb::Transform< typename TFirstTransform::ScalarType, TFirstTransform::InputSpaceDimension, TSecondTransform::OutputSpaceDimension >
Cotb::CompositeTransform< TFirstTransform, TSecondTransform, TScalarType, NInputDimensions, NOutputDimensions >	Class which compose two itk::Transform to obtain one itk::Transform T1 T2 T3 (x, y) -> (x', y') -> (x'', y'') => (x, y) -> (x'', y'')
►Cotb::Transform< TScalarType, NInputDimensions, NOutputDimensions >	Class to overload method passed to virtual pure in ITK V4
►Cotb::SensorTransformBase< TScalarType, 3, 2 >
Cotb::RPCTransformBase< TScalarType, NInputDimensions, NOutputDimensions >	Base projection class based on the RPC method
Cotb::SarTransformBase< TScalarType, NInputDimensions, NOutputDimensions >	Base projection class based on the Sar model
Cotb::Spot5TransformBase< TScalarType, NInputDimensions, NOutputDimensions >	Base projection class based on the Spot5 model
Cotb::TransformationFunctorDispatcher< TransformationFunctor, TransformedElementType, FieldTransformationPolicy >
►Cotb::TransformationFunctorDispatcher< TransformationFunctor, TransformationFunctor::TransformedElementType, FieldCopyTransformation >
Cotb::DefaultGeometriesToGeometriesFilter< TransformationFunctor, FieldTransformationPolicy >
Cotb::TransformationFunctorDispatcher< TransformationFunctorType, TransformedElementType, FieldCopyTransformation >
Cotb::SamplingRateCalculator::Triplet
►Cstd::true_type
Cotb::IsNeighborhood< const itk::ConstNeighborhoodIterator< Image< T > > & >	Partial specialisation for const ConstNeighborhoodIterator<Image::T> &
Cotb::IsNeighborhood< const itk::ConstNeighborhoodIterator< VectorImage< T > > & >	Partial specialisation for const ConstNeighborhoodIterator<VectorImage::T> &
Cotb::mpl::is_array< itk::VariableLengthVector< T > >
Cotb::mpl::is_array< itk::VariableLengthVectorExpression< TExpr1, TExpr2, TBinaryOp > >
Cotb::internal::tuple_index< Arg, Tuple >	Retrieve index of a type in tuple if exists
Cotb::internal::tuple_index< Arg, std::tuple< Arg, Args... > >
Cotb::internal::tuple_index< Arg, std::tuple< NotMatching, Args... > >
►CIsSuitableType::type
Cotb::IsSuitableType< itk::FixedArray< T, N > >	Unwrap FixedArray
Cotb::IsSuitableType< itk::RGBAPixel< T > >	Unwrap RGBAPixel
Cotb::IsSuitableType< itk::RGBPixel< T > >	Unwrap RGBPixel
Cotb::IsSuitableType< itk::VariableLengthVector< T > >	Unwrap VariableLengthVector
Cotb::IsSuitableType< std::complex< T > >	Unwrap complex
►Cstd::is_scalar::type
Cotb::IsSuitableType< T >	Helper struct to check if a type can be used as pixel type
►Citk::UnaryFunctorImageFilter
Cotb::ChangeLabelImageFilter< TInputImage, TOutputImage >	Change Sets of Labels
Cotb::ChangeNoDataValueFilter< TInputImage, TOutputImage >	Change no-data flags and values and replace them in image
Cotb::CloudDetectionFilter< TInputImage, TOutputImage, TFunction >	Applies cloud detection functor to an image
Cotb::CloudEstimatorFilter< TInputImage, TOutputImage, TFunction >	Filter to help with the cloud detection
Cotb::ComplexToIntensityImageFilter< TInputImage, TOutputImage >	Computes pixel-wise the intensity of a complex image
Cotb::ComplexToVectorImageCastFilter< TInputImage, TOutputImage >	Transform a complex image into a 2 channels vector image. The first channel is the real part, the second the imaginary one
Cotb::ConcatenateScalarValueImageFilter< TInputImage, TOutputImage >	Applies a projective projection to each pixel of an image
Cotb::HessianToScalarImageFilter< TInputImage, TOutputImage >	TODO
Cotb::ImageToNoDataMaskFilter< TInputImage, TOutputImage >	Builds a no-data mask image from no-data flags and values
Cotb::ImageToVectorImageCastFilter< TInputImage, TOutputVectorImage >	This is a helper class that convert an otb::Image into a single-channel otb::VectorImage
Cotb::ImaginaryImageToComplexImageFilter< TInputImageImaginaryPart, TOutputImage >	Computes pixel-wise the complex image of a imaginary image
Cotb::Log10ThresholdedImageFilter< TInputImage, TOutputImage >	Computes the 10 * std::log10(x) pixel-wise with a threshold for the lowest values
Cotb::MultiplyByScalarImageFilter< TInputImage, TOutputImage >	TODO
Cotb::RealImageToComplexImageFilter< TInputImageRealPart, TOutputImage >	Computes pixel-wise the complex image of a real image
Cotb::SOMbasedImageFilter< TInputImage, TOutputImage, TDistanceMetric, TMap >	This class perform the substitution between initial input image pixels and the winning neurons of a SOM
Cotb::ShiftScaleVectorImageFilter< TInputImage, TOutputImage >	This filter performs a shift and scaling of a vector image on a per band basis
Cotb::TerraSarBrightnessImageFilter< TInputImage, TOutputImage >	Calculates the brightness of TerraSar sensor images
Cotb::VectorImageToAmplitudeImageFilter< TInputImage, TOutputImage >	This filter returns the the amplitude of the pixel vector
Cotb::VectorRescaleIntensityImageFilter< TInputImage, TOutputImage >	This filter performs a rescaling of a vector image on a per band basis
Cotb::WaterSqrtSpectralAngleImageFilter< TInputVectorImage, TOutputImage, TFunction >	Compute a radiometric water indice
Cotb::Functor::UnConstrainedLeastSquareFunctor< TInput, TOutput, TPrecision >	Solves a least square system on a pixel
Cotb::Functor::UniformAlphaBlendingFunctor< TInputPixel, TInputPixel2, TOutputPixel >	Implements simple blending For each channel the blending function is as follows:
Cotb::ImageIOBase::UnknownType
CUtils	Utils operations
Cotb::Functor::VariadicAdd< TOut, TIns >	This functor adds any number of compile time scalar inputs
Cotb::Functor::VariadicConcatenate< TOut, TIns >	This functor concatenates any number of input of scalar type or VariableLengthVector
Cotb::VarSol	VarSol operations
Cotb::Functor::VectorAffineTransform< TInput, TOutput >	This functor performs a per band linear transform of its input
Cotb::Functor::VectorCast< TInput, TOutput >	This functor can be used to convert scalar value to VariableLengthVector with another precision a size of 1
Cotb::Functor::VectorChangeLabel< TInput, TOutput >
Cotb::Functor::VectorComplexToVector< TInput, TOutput >
Cotb::VectorDataKeywordlist	This class handle the metadata of vector data
►Citk::VectorImage
Cotb::VectorImage< TNeuron::ComponentType, 2 >
Cotb::VectorImage< TPixel, VImageDimension >	Creation of an "otb" vector image which contains metadata
Cotb::Accessor::VectorImageToASPixelAccessor< T >	Give access to a Vector pixel type as if it were a RGBPixel type
Cotb::Functor::VectorShiftScale< TInput, TOutput >	This functor performs a per band linear transform of its input
Cotb::PersistentSamplingFilterBase< TInputImage, TMaskImage >::VectorThreadStruct
Cotb::Functor::VectorToAmplitudeFunctor< TInput, TOutput >
Cotb::Functor::VerticalSobelOperator< TInput, TOutput >	Performs the calculation of vertical Sobel derivation
Cotb::polarimetry_tags::vh
Cotb::polarimetry_tags::vv
►Citk::WarpImageFilter
Cotb::StreamingWarpImageFilter< TInputImage, TOutputImage, TDisplacementField >	This class acts like the itk::WarpImageFilter, but it does not request the largest possible region of the image to warp
Cotb::WaveletOperator< TMotherWaveletOperator, TDirectionOfTransformation, TPixel, VDimension, TAllocator >	A Generic NeighborhoodOperator wavelets filter set defined for templation
Cotb::Function::WelchWindowFunction< TInput, TOutput >	Window function for sinc interpolation
Cotb::Projection::WGS84Ellipsoid< TScalarType >	Structure holding the ellipsoid parameters for WGS84
►Cotb::WriterWatcherBase	This class is an abstract class Provides an interface to progress task mechanic
Cotb::StandardWriterWatcher	This class shows the percentage progress execution of the pipeline filtering process
Cotb::SarSensorModel::ZeroDopplerInfo
Cotb::internals::ZipIterator< TImageIterator, ConstOrMutable >