affine_trans_image_size
— Apply an arbitrary affine 2D transformation to an image and specify
the output image size.
affine_trans_image_size(Image : ImageAffineTrans : HomMat2D, Interpolation, Width, Height : )
affine_trans_image_size
applies an arbitrary affine 2D
transformation, i.e., scaling, rotation, translation, and slant
(skewing), to the images given in Image
and returns the
transformed images in ImageAffineTrans
. The affine
transformation is described by the homogeneous transformation matrix
given in HomMat2D
, which can be created using the operators
hom_mat2d_identity
, hom_mat2d_scale
,
hom_mat2d_rotate
, hom_mat2d_translate
, etc., or be
the result of operators like vector_angle_to_rigid
.
The components of the homogeneous transformation matrix are interpreted as follows: The row coordinate of the image corresponds to x and the column coordinate corresponds to y of the coordinate system in which the transformation matrix was defined. This is necessary to obtain a right-handed coordinate system for the image. In particular, this assures that rotations are performed in the correct direction. Note that the (x,y) order of the matrices quite naturally corresponds to the usual (row,column) order for coordinates in the image.
The region of the input image is ignored, i.e., assumed to be the full rectangle of the image. The region of the resulting image is set to the transformed rectangle of the input image. If necessary, the resulting image is filled with zero (black) outside of the region of the original image.
Generally, transformed points will lie between pixel coordinates.
Therefore, an appropriate interpolation scheme has to be used. The
interpolation can also be used to avoid aliasing effects for scaled
images. The quality and speed of the interpolation can be set by
the parameter Interpolation
:
Nearest-neighbor interpolation: The gray value is determined from the nearest pixel's gray value (possibly low quality, very fast).
Bilinear interpolation. The gray value is determined from the four nearest pixels through bilinear interpolation. If the affine transformation contains a scaling with a scale factor < 1, no smoothing is performed, which may cause severe aliasing effects (medium quality and run time).
Bicubic interpolation. The gray value is determined from the nearest pixels through bicubic interpolation. If the affine transformation contains a scaling with a scale factor < 1, no smoothing is performed, which may cause severe aliasing effects (high quality for enlargements, slow).
Bilinear interpolation. The gray value is determined from the four nearest pixels through bilinear interpolation. If the affine transformation contains a scaling with a scale factor < 1, a kind of mean filter is used to prevent aliasing effects (medium quality and run time).
Bilinear interpolation. The gray value is determined from the four nearest pixels through bilinear interpolation. If the affine transformation contains a scaling with a scale factor < 1, a kind of Gaussian filter is used to prevent aliasing effects (high quality, slow).
In addition, the system parameter 'int_zooming' (see
set_system
) affects the accuracy of the transformation. If
'int_zooming' is set to 'true' , the transformation
for byte, int2 and uint2 images is carried out internally using
fixed point arithmetic, leading to much shorter execution times.
However, the accuracy of the transformed gray values is smaller in
this case. For byte images, the differences to the more accurate
calculation (using 'int_zooming' = 'false' ) is
typically less than two gray levels. Correspondingly, for int2 and
uint2 images, the gray value differences are less than 1/128 times
the dynamic gray value range of the image, i.e., they can be as
large as 512 gray levels if the entire dynamic range of 16 bit is
used. When using fixed point arithmetic, the domain of
resulting images can differ as well.
Additionally, if a large scale factor is applied and a large
output image is obtained, then undefined gray values at the lower
and at the right image border may result. The maximum width
of this border of undefined gray values can be
estimated as , where S is the scale factor in one dimension
and I is the size of the output image in the corresponding
dimension. For real images, the parameter 'int_zooming'
does not affect the accuracy, since the internal calculations are
always done using floating point arithmetic.
The size of the target image is specified by the parameters
Width
and Height
. Note that the image is always
clipped at the left and upper edge, i.e., all image parts that have
negative coordinates after the transformation are clipped. If the
affine transformation (in particular, the translation) is chosen
appropriately, a part of the image can be transformed as well as
cropped in one call. This is useful, for example, when using the
variation model (see compare_variation_model
), because with
this mechanism only the parts of the image that should be examined,
are transformed.
The region of the input image is ignored.
affine_trans_image_size
does not use the HALCON standard
coordinate system (with the origin in the center of the upper left
pixel), but instead uses the same coordinate system as in
affine_trans_pixel
, i.e., the origin lies in the upper left
corner of the upper left pixel. Therefore, applying
affine_trans_image_size
corresponds to a chain of
transformations (see affine_trans_pixel
), which is applied
to each point of the image (input and output pixels as homogeneous
vectors). As an effect, you might get unexpected results when
creating affine transformations based on coordinates that are
derived from the image, e.g., by operators like
area_center_gray
. For example, if you use this operator to
calculate the center of gravity of a rotationally symmetric image
and then rotate the image around this point using
hom_mat2d_rotate
, the resulting image will not lie on the
original one. In such a case, you can compensate this effect by
applying the following translations to HomMat2D
before
using it in affine_trans_image_size
:
hom_mat2d_translate(HomMat2D, 0.5, 0.5, HomMat2DTmp) hom_mat2d_translate_local(HomMat2DTmp, -0.5, -0.5, HomMat2DAdapted) affine_trans_image_size(Image, ImageAffineTrans, HomMat2DAdapted, 'constant', Width, Height)
For an explanation of the different 2D coordinate systems used in HALCON, see the introduction of chapter Transformations / 2D Transformations.
Image
(input_object) (multichannel-)image(-array) →
object (byte / int2 / uint2 / real)
Input image.
ImageAffineTrans
(output_object) (multichannel-)image(-array) →
object (byte / int2 / uint2 / real)
Transformed image.
HomMat2D
(input_control) hom_mat2d →
(real)
Input transformation matrix.
Interpolation
(input_control) string →
(string)
Type of interpolation.
Default value: 'constant'
List of values: 'bicubic' , 'bilinear' , 'constant' , 'nearest_neighbor' , 'weighted'
Width
(input_control) extent.x →
(integer)
Width of the output image.
Default value: 640
Suggested values: 128, 160, 192, 256, 320, 384, 512, 640, 768
Height
(input_control) extent.y →
(integer)
Height of the output image.
Default value: 480
Suggested values: 120, 128, 144, 240, 256, 288, 480, 512, 576
If the matrix HomMat2D
represents an affine transformation
(i.e., not a projective transformation),
affine_trans_image_size
returns TRUE. If the input is empty
the behavior can be set via
set_system(::'no_object_result',<Result>:)
. If necessary,
an exception is raised.
hom_mat2d_identity
,
hom_mat2d_translate
,
hom_mat2d_rotate
,
hom_mat2d_scale
,
hom_mat2d_reflect
affine_trans_image
,
zoom_image_size
,
zoom_image_factor
,
mirror_image
,
rotate_image
,
affine_trans_region
Foundation