CVBpy 14.1
NonLinearTransformation Class Reference

Object implementing the non linear polynomially approximated transform implemented in the CVB Foundation package. More...

Inherits object.

Public Member Functions

cvb.foundation.NonLinearTransformation from_calibration_pattern (cvb.ImagePlane plane, int style, int contrast, int grid_spacing, int min_contrast, float max_ratio, int order, Optional[cvb.Area2D] aoi)
 Create a new transformation object by automatically extracting the pixel lists required for creating a NonLinearTransformation object. More...
 
cvb.foundation.NonLinearTransformation from_position_lists (List[cvb.Point2D] original_pixels, List[cvb.Point2D] transformed_pixels, int order)
 Create a non linear transformation that - approximately - matches the set of original_pixels to the set of transformed_pixels. More...
 
cvb.Image inverse_transform_image (self, cvb.Image image, cvb.Size2D target_size, cvb.Point2D target_offset)
 Back transform an image with this nonlinear transformation. More...
 
Union[cvb.Point2D, List[cvb.Point2D]] inverse_transform_points (self, Union[cvb.Point2D, List[cvb.Point2D]] points)
 Back transform a point or a sequence of points with this nonlinear transformation. More...
 
cvb.foundation.NonLinearTransformation load (str file_name)
 Load a saved transformation from a file. More...
 
None save (self, str file_name)
 Write the transformation to a file. More...
 
cvb.Image transform_image (self, cvb.Image image, cvb.Size2D target_size, cvb.Point2D target_offset)
 Transform an image with this nonlinear transformation. More...
 
Union[cvb.Point2D, List[cvb.Point2D]] transform_points (self, Union[cvb.Point2D, List[cvb.Point2D]] points)
 Transform a point or a sequence of points with this nonlinear transformation. More...
 
cvb.Rect transform_rect (self, cvb.Rect rect)
 Transform a rectangle with this nonlinear transformation. More...
 

Properties

 coefficients_x = property
 List[float]: Return an array of the coefficients used for the transformation of x-coordinates.
 
 coefficients_x_inverse = property
 List[float]: Return an array of the coefficients used for the inverse transformation of x-coordinates.
 
 coefficients_y = property
 List[float]: Return an array of the coefficients used for the transformation of y-coordinates.
 
 coefficients_y_inverse = property
 List[float]: Return an array of the coefficients used for the inverse transformation of y-coordinates.
 
 order = property
 int: Gets the transformation order.
 

Detailed Description

Object implementing the non linear polynomially approximated transform implemented in the CVB Foundation package.

Load a saved transformation from a file.

Parameters

file_name : str Name of the file to load.

Member Function Documentation

◆ from_calibration_pattern()

cvb.foundation.NonLinearTransformation from_calibration_pattern ( cvb.ImagePlane  plane,
int  style,
int  contrast,
int  grid_spacing,
int  min_contrast,
float  max_ratio,
int  order,
Optional[cvb.Area2D aoi 
)

Create a new transformation object by automatically extracting the pixel lists required for creating a NonLinearTransformation object.

The image plane given to this method needs to contain a calibration pattern as generated by the method cvb.foundation.create_calibration_pattern(): A regularly spaced matrix of dots, the distance between the dots in x- and y-direction should be 2.5 times the diameter of the dots, if an asymmetric pattern was used, the bigger dots should have 2.5 times the area of the smaller dots (meaning that their radius is sqrt(2.5) times the radius of the small dots). Note that, although the area of interest is given as a cvb.Area2D here (and in the processing of the cvb.Area2D the image's coordinate system will be respected), the actual output of this method uses CoordinateSystemType.PixelCoordinates! This seemingly inconsistent mix in this case is in fact useful, because a cvb.Area2D will better capture the actual location of a calibration pattern, especially if the image has been rotated, than a cvb.Rect style area of interest. But the calibration functions working on the output of cvb.foundation.extract_calibration_lists() usually assume that the pixel lists are given in pixel coordinates. To avoid misunderstandings and complications in the interpretation of the image content, it is recommended to use a default coordinate system on the input image.The minimum contrast (min_contrast) value to be set depends on the quality of the image taken from the pattern, but in a typical situation this contrast should not drop below 64 gray values, otherwise it might become difficult to extract the calibration points. The maximum ration (max_ratio) value will be used to identify outliers when looking for calibration dots. It should be set high enough to allow for the area variations to be expected due to perspective distortions and small enough to eliminate the candidates that are either too big or too small to be valid calibration pattern dots. Typically, values of about 3.0 to 5.0 are big enough - even if there is notable perspective distortion visible in the images. If an asymmetric calibration pattern has been selected, the ratio used for calculation will be adapted accordingly.

Parameters

plane : cvb.ImagePlane Image plane to work on.

style : int Calibration pattern style visible in the image (see cvb.foundation.CalibrationPatternStyle).

contrast : int Selects whether the image shows cvb.foundation.CalibrationPatternContrast.BlackOnWhite or cvb.foundation.CalibrationPatternContrast.WhiteOnBlack dots.

grid_spacing : int Spacing of the calibration dot grid in the target image. Defines the distance of the points that will end up in the transformed pixels.

min_contrast : int Minimum gray value contrast between the object and the background of the calibration target pattern.

max_ratio : float Maximum ratio between the biggest and the smallest calibration dot.

order : int Polynomial order of the transformation to be generated.

aoi : Optional[cvb.Area2D] Area of interest in which to look for the calibration pattern's dots (default entire image).

Returns

cvb.foundation.NonLinearTransformation The computed transformation.

◆ from_position_lists()

cvb.foundation.NonLinearTransformation from_position_lists ( List[cvb.Point2D original_pixels,
List[cvb.Point2D transformed_pixels,
int  order 
)

Create a non linear transformation that - approximately - matches the set of original_pixels to the set of transformed_pixels.

Parameters

original_pixels : List[cvb.Point2D] Originial pixel locations. The pixels as measured from an image.

transformed_pixels : List[cvb.Point2D] Transformed pixels. The locations the corresponding pixels from originalPixels should ideally have.

order : int Polynomial order of the transformation to generate.

Returns

cvb.foundation.NonLinearTransformation The computed transformation.

◆ inverse_transform_image()

cvb.Image inverse_transform_image (   self,
cvb.Image  image,
cvb.Size2D  target_size,
cvb.Point2D  target_offset 
)

Back transform an image with this nonlinear transformation.

Parameters

image : cvb.Image Image to transform.

target_size : cvb.Size2D Target size of the transformed image.

target_offset : cvb.Point2D Origin offset of the transformed image.

Returns

cvb.Image The transformed image.

◆ inverse_transform_points()

Union[cvb.Point2D, List[cvb.Point2D]] inverse_transform_points (   self,
Union[cvb.Point2D, List[cvb.Point2D]]  points 
)

Back transform a point or a sequence of points with this nonlinear transformation.

Parameters

points : Union[cvb.Point2D, List[cvb.Point2D]] Point(s) to transform.

Returns

Union[cvb.Point2D, List[cvb.Point2D]] The transformed point(s).

◆ load()

cvb.foundation.NonLinearTransformation load ( str  file_name)

Load a saved transformation from a file.

Parameters

file_name : str File to load.

Returns

cvb.foundation.NonLinearTransformation Loaded nonlinear transformation.

◆ save()

None save (   self,
str  file_name 
)

Write the transformation to a file.

Parameters

file_name : str Path to save to.

◆ transform_image()

cvb.Image transform_image (   self,
cvb.Image  image,
cvb.Size2D  target_size,
cvb.Point2D  target_offset 
)

Transform an image with this nonlinear transformation.

Parameters

image : cvb.Image Image to transform.

target_size : cvb.Size2D Target size of the transformed image.

target_offset : cvb.Point2D Origin offset of the transformed image.

Returns

cvb.Image The transformed image.

◆ transform_points()

Union[cvb.Point2D, List[cvb.Point2D]] transform_points (   self,
Union[cvb.Point2D, List[cvb.Point2D]]  points 
)

Transform a point or a sequence of points with this nonlinear transformation.

Parameters

points : Union[cvb.Point2D, List[cvb.Point2D]] Point(s) to transform.

Returns

Union[cvb.Point2D, List[cvb.Point2D]] The transformed point(s).

◆ transform_rect()

cvb.Rect transform_rect (   self,
cvb.Rect  rect 
)

Transform a rectangle with this nonlinear transformation.

The transformed rect is an estimate of the target dimensions needed for a transformed image. Due to the non linearity of the transformation it may not be correct. Consider it a best guess.

Parameters

rect : cvb.Rect Rectangle to transform.

Returns

cvb.Rect The transformed rectangle.