OpeningLine3d
Performs a three-dimensional opening using a structuring element matching with a line.
Access to parameter description
For an introduction:
The erosion line is oriented in the direction given by ($\theta$, $\varphi$) in spherical coordinates as often used in mathematics (azimuthal angle, $\theta$ and polar angle, $\varphi$). This direction is described with the following formula: $$V=\left[\begin{array}{c}; v_x\\ v_y\\ v_z\end{array}\right] = \left[\begin{array}{c}; \sin(\varphi)\cos(\theta)\\ \sin(\varphi)\sin(\theta)\\ \cos(\varphi)\end{array}\right]$$ This direction can be illustrated on the unit sphere:
Figure 1. Azimuthal and polar angles on the unit sphere
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. 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
Access to parameter description
For an introduction:
- section Mathematical Morphology
- section Introduction To Opening
The erosion line is oriented in the direction given by ($\theta$, $\varphi$) in spherical coordinates as often used in mathematics (azimuthal angle, $\theta$ and polar angle, $\varphi$). This direction is described with the following formula: $$V=\left[\begin{array}{c}; v_x\\ v_y\\ v_z\end{array}\right] = \left[\begin{array}{c}; \sin(\varphi)\cos(\theta)\\ \sin(\varphi)\sin(\theta)\\ \cos(\varphi)\end{array}\right]$$ This direction can be illustrated on the unit sphere:
Figure 1. Azimuthal and polar angles on the unit sphere
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. 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 outputImage.
// Function prototype
std::shared_ptr< iolink::ImageView > openingLine3d( std::shared_ptr< iolink::ImageView > inputImage, double thetaAngle, double phiAngle, uint32_t kernelRadius, OpeningLine3d::BorderPolicy borderPolicy, std::shared_ptr< iolink::ImageView > outputImage = nullptr );
This function returns outputImage.
// Function prototype.
opening_line_3d(input_image: idt.ImageType,
theta_angle: float = 0,
phi_angle: float = 0,
kernel_radius: int = 3,
border_policy: OpeningLine3d.BorderPolicy = OpeningLine3d.BorderPolicy.LIMITED,
output_image: idt.ImageType = None) -> idt.ImageType
This function returns outputImage.
// Function prototype.
public static IOLink.ImageView
OpeningLine3d( IOLink.ImageView inputImage,
double thetaAngle = 0,
double phiAngle = 0,
UInt32 kernelRadius = 3,
OpeningLine3d.BorderPolicy borderPolicy = ImageDev.OpeningLine3d.BorderPolicy.LIMITED,
IOLink.ImageView outputImage = null );
Class Syntax
Parameters
| 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.
|
Enumeration | LIMITED | |||||
|
thetaAngle |
The azimuthal angle in degrees. | Float64 | Any value | 0 | ||||
|
phiAngle |
The polar angle in degrees. | Float64 | Any value | 0 | ||||
|
kernelRadius |
The length of the linear structuring element in voxels. | UInt32 | >=1 | 3 | ||||
 |
outputImage |
The output image. Its dimensions and type are forced to the same values as the input image. | Image | nullptr | |||||
| Parameter Name | Description | Type | Supported Values | Default Value | |||||
|---|---|---|---|---|---|---|---|---|---|
|
input_image |
The input image. The image type can be integer or float. | image | Binary, Label, Grayscale or Multispectral | None | ||||
|
border_policy |
The border policy to apply.
|
enumeration | LIMITED | |||||
|
theta_angle |
The azimuthal angle in degrees. | float64 | Any value | 0 | ||||
|
phi_angle |
The polar angle in degrees. | float64 | Any value | 0 | ||||
|
kernel_radius |
The length of the linear structuring element in voxels. | uint32 | >=1 | 3 | ||||
|
output_image |
The output image. Its dimensions and type are forced to the same values as the input image. | image | None | |||||
| 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 | null | ||||
|
borderPolicy |
The border policy to apply.
|
Enumeration | LIMITED | |||||
|
thetaAngle |
The azimuthal angle in degrees. | Float64 | Any value | 0 | ||||
|
phiAngle |
The polar angle in degrees. | Float64 | Any value | 0 | ||||
|
kernelRadius |
The length of the linear structuring element in voxels. | UInt32 | >=1 | 3 | ||||
|
outputImage |
The output image. Its dimensions and type are forced to the same values as the input image. | Image | null | |||||
Object Examples
auto foam = readVipImage( std::string( IMAGEDEVDATA_IMAGES_FOLDER ) + "foam.vip" ); OpeningLine3d openingLine3dAlgo; openingLine3dAlgo.setInputImage( foam ); openingLine3dAlgo.setThetaAngle( 0 ); openingLine3dAlgo.setPhiAngle( 0 ); openingLine3dAlgo.setKernelRadius( 3 ); openingLine3dAlgo.setBorderPolicy( OpeningLine3d::BorderPolicy::EXTENDED ); openingLine3dAlgo.execute(); std::cout << "outputImage:" << openingLine3dAlgo.outputImage()->toString();
foam = imagedev.read_vip_image(imagedev_data.get_image_path("foam.vip"))
opening_line_3d_algo = imagedev.OpeningLine3d()
opening_line_3d_algo.input_image = foam
opening_line_3d_algo.theta_angle = 0
opening_line_3d_algo.phi_angle = 0
opening_line_3d_algo.kernel_radius = 3
opening_line_3d_algo.border_policy = imagedev.OpeningLine3d.EXTENDED
opening_line_3d_algo.execute()
print("output_image:", str(opening_line_3d_algo.output_image))
ImageView foam = Data.ReadVipImage( @"Data/images/foam.vip" );
OpeningLine3d openingLine3dAlgo = new OpeningLine3d
{
inputImage = foam,
thetaAngle = 0,
phiAngle = 0,
kernelRadius = 3,
borderPolicy = OpeningLine3d.BorderPolicy.EXTENDED
};
openingLine3dAlgo.Execute();
Console.WriteLine( "outputImage:" + openingLine3dAlgo.outputImage.ToString() );
Function Examples
auto foam = readVipImage( std::string( IMAGEDEVDATA_IMAGES_FOLDER ) + "foam.vip" ); auto result = openingLine3d( foam, 0, 0, 3, OpeningLine3d::BorderPolicy::EXTENDED ); std::cout << "outputImage:" << result->toString();
foam = imagedev.read_vip_image(imagedev_data.get_image_path("foam.vip"))
result = imagedev.opening_line_3d(foam, 0, 0, 3, imagedev.OpeningLine3d.EXTENDED)
print("output_image:", str(result))
ImageView foam = Data.ReadVipImage( @"Data/images/foam.vip" ); IOLink.ImageView result = Processing.OpeningLine3d( foam, 0, 0, 3, OpeningLine3d.BorderPolicy.EXTENDED ); Console.WriteLine( "outputImage:" + result.ToString() );