Opening3d

Performs a three-dimensional opening using a structuring element matching with a with a full or partial cube.

Access to parameter description

For an introduction:

section Mathematical Morphology
section Introduction To Opening

This algorithm successively runs an Erosion3d and a Dilation3d with the same kernel.
The kernelRadius parameter tunes the number of iterations of each operation, which sets the kernel size.
This algorithm uses a basic structuring element with 6, 18 or 26 neighbors, according to the neighborhood parameter.

<b> Figure 1.</b> Structuring elements: 6, 18 and 26 neighbors

Figure 1. Structuring elements: 6, 18 and 26 neighbors

With a classic implementation, morphological opening systematically considers areas out of the image as a replication of the image borders at each step of the algorithm. Therefore, when applying an opening, some thin object parts cut by the image borders may be removed at the erosion step and not be restored after the dilation, while one would expect to keep them. The borderPolicy parameter manages this case. The default mode, LIMITED, corresponds to the classic behavior. The EXTENDED mode properly manages image borders by extending them by a size equal to the structuring element's. Therefore, this mode can be slower and more memory consuming, especially when the structuring element size is high.
This option is illustrated in the Opening2d documentation (Figure 2).

See also

Function Syntax

This function returns the outputImage output parameter.

// Function prototype.
std::shared_ptr< iolink::ImageView >
opening3d( std::shared_ptr< iolink::ImageView > inputImage,
           uint32_t kernelRadius,
           Opening3d::Neighborhood neighborhood,
           Opening3d::BorderPolicy borderPolicy,
           std::shared_ptr< iolink::ImageView > outputImage = NULL );

This function returns the outputImage output parameter.

// Function prototype.
opening_3d( input_image,
            kernel_radius = 3,
            neighborhood = Opening3d.Neighborhood.CONNECTIVITY_26,
            border_policy = Opening3d.BorderPolicy.LIMITED,
            output_image = None )

This function returns the outputImage output parameter.

// Function prototype.
public static IOLink.ImageView
Opening3d( IOLink.ImageView inputImage,
           UInt32 kernelRadius = 3,
           Opening3d.Neighborhood neighborhood = ImageDev.Opening3d.Neighborhood.CONNECTIVITY_26,
           Opening3d.BorderPolicy borderPolicy = ImageDev.Opening3d.BorderPolicy.LIMITED,
           IOLink.ImageView outputImage = null );

Class Syntax

// Command constructor.
Opening3d();

// Get method of the inputImage parameter.
std::shared_ptr< iolink::ImageView > inputImage() const;
// Set method of the inputImage parameter.
void setInputImage( std::shared_ptr< iolink::ImageView > inputImage );

// Get method of the kernelRadius parameter.
uint32_t kernelRadius() const;
// Set method of the kernelRadius parameter.
void setKernelRadius( const uint32_t& kernelRadius );

// Get method of the neighborhood parameter.
Opening3d::Neighborhood neighborhood() const;
// Set method of the neighborhood parameter.
void setNeighborhood( const Opening3d::Neighborhood& neighborhood );

// Get method of the borderPolicy parameter.
Opening3d::BorderPolicy borderPolicy() const;
// Set method of the borderPolicy parameter.
void setBorderPolicy( const Opening3d::BorderPolicy& borderPolicy );

// Get method of the outputImage parameter.
std::shared_ptr< iolink::ImageView > outputImage() const;
// Set method of the outputImage parameter.
void setOutputImage( std::shared_ptr< iolink::ImageView > outputImage );

// Method to launch the command.
void execute();

// Property of the inputImage parameter.
Opening3d.input_image
// Property of the kernelRadius parameter.
Opening3d.kernel_radius
// Property of the neighborhood parameter.
Opening3d.neighborhood
// Property of the borderPolicy parameter.
Opening3d.border_policy
// Property of the outputImage parameter.
Opening3d.output_image

// Method to launch the command.
execute()

// Command constructor.
Opening3d()

// Property of the inputImage parameter.
Opening3d.inputImage
// Property of the kernelRadius parameter.
Opening3d.kernelRadius
// Property of the neighborhood parameter.
Opening3d.neighborhood
// Property of the borderPolicy parameter.
Opening3d.borderPolicy
// Property of the outputImage parameter.
Opening3d.outputImage

// Method to launch the command.
Execute()

Parameters

Class Name	Opening3d

Parameter Name

Description

Type

Supported Values

Default Value

inputImage

The input image. The image type can be integer or float.

Image

Binary, Label, Grayscale or Multispectral

nullptr

borderPolicy

The border policy to apply.

LIMITED	The limited mode is faster to compute, but can produce unexpected results for particles close to the image border.
EXTENDED	The Extended mode is slower to compute, but produces the expected results for particles close to the image border.

Enumeration

LIMITED

kernelRadius

The number of iterations (the half size of the structuring element, in voxels). A cube structuring element always has an odd side length (3x3x3, 5x5x5, etc.) which is defined by twice the kernel radius + 1.

UInt32

>=1

neighborhood

The 3D neighborhood configuration.

CONNECTIVITY_6	The structuring element is composed of voxels with a common face with the voxel of interest.
CONNECTIVITY_18	The structuring element is composed of voxels with at least one common edge.
CONNECTIVITY_26	The structuring element is a full cube.

Enumeration

CONNECTIVITY_26

outputImage

The output image. Its dimensions and type are forced to the same values as the input image.

Image

nullptr

Object Examples

auto foam = readVipImage( std::string( IMAGEDEVDATA_IMAGES_FOLDER ) + "foam.vip" );

Opening3d opening3dAlgo;
opening3dAlgo.setInputImage( foam );
opening3dAlgo.setKernelRadius( 3 );
opening3dAlgo.setNeighborhood( Opening3d::Neighborhood::CONNECTIVITY_26 );
opening3dAlgo.setBorderPolicy( Opening3d::BorderPolicy::EXTENDED );
opening3dAlgo.execute();

std::cout << "outputImage:" << opening3dAlgo.outputImage()->toString();

foam = imagedev.read_vip_image(imagedev_data.get_image_path("foam.vip"))

opening_3d_algo = imagedev.Opening3d()
opening_3d_algo.input_image = foam
opening_3d_algo.kernel_radius = 3
opening_3d_algo.neighborhood = imagedev.Opening3d.CONNECTIVITY_26
opening_3d_algo.border_policy = imagedev.Opening3d.EXTENDED
opening_3d_algo.execute()

print( "output_image:", str( opening_3d_algo.output_image ) );

ImageView foam = Data.ReadVipImage( @"Data/images/foam.vip" );

Opening3d opening3dAlgo = new Opening3d
{
    inputImage = foam,
    kernelRadius = 3,
    neighborhood = Opening3d.Neighborhood.CONNECTIVITY_26,
    borderPolicy = Opening3d.BorderPolicy.EXTENDED
};
opening3dAlgo.Execute();

Console.WriteLine( "outputImage:" + opening3dAlgo.outputImage.ToString() );

Function Examples

auto foam = readVipImage( std::string( IMAGEDEVDATA_IMAGES_FOLDER ) + "foam.vip" );

auto result = opening3d( foam, 3, Opening3d::Neighborhood::CONNECTIVITY_26, Opening3d::BorderPolicy::EXTENDED );

std::cout << "outputImage:" << result->toString();

foam = imagedev.read_vip_image(imagedev_data.get_image_path("foam.vip"))

result = imagedev.opening_3d( foam, 3, imagedev.Opening3d.CONNECTIVITY_26, imagedev.Opening3d.EXTENDED )

print( "output_image:", str( result ) );

ImageView foam = Data.ReadVipImage( @"Data/images/foam.vip" );

IOLink.ImageView result = Processing.Opening3d( foam, 3, Opening3d.Neighborhood.CONNECTIVITY_26, Opening3d.BorderPolicy.EXTENDED );

Console.WriteLine( "outputImage:" + result.ToString() );

Opening3d

- Function Syntax

+ Class Syntax

Parameters

Object Examples

Function Examples

Function Syntax

Class Syntax