edges_sub_pix
— Extract sub-pixel precise edges using Deriche, Lanser, Shen, or Canny
filters.
edges_sub_pix
detects step edges using recursively implemented
filters (according to Deriche, Lanser and Shen) or the conventionally
implemented “derivative of Gaussian” filter (using filter masks)
proposed by Canny. Thus, the following edge operators are
available:
'deriche1', 'lanser1', 'deriche2', 'lanser2', 'shen', 'mshen', 'canny', 'sobel', and 'sobel_fast'
(parameter Filter
).
The extracted edges are returned as sub-pixel precise XLD contours
in Edges
. For all edge operators except
'sobel_fast' , the following attributes are defined for each
edge point (see get_contour_attrib_xld
for further details):
Gives the direction of the edge (not of the XLD contour), calculated from the image gradients in horizontal and vertical direction. The angles [rad] are given with respect to the column axis of the image.
Direction of the normal vectors to the contour in radians (oriented such that the normal vectors point to the right side of the contour as the contour is traversed from start to end point; the angles are given with respect to the row axis of the image).
Edge amplitude (gradient magnitude).
The “filter width” (i.e., the amount of smoothing) can be chosen
arbitrarily for all edge operators except 'sobel' and
'sobel_fast' , and can be estimated by calling
info_edges
for concrete values of the parameter
Alpha
. For all filters (Deriche, Lanser and Shen filters), the
“filter width” decreases for increasing Alpha
. The only exception
is the Canny filter, where an increasing Alpha
also causes an
increase of the “filter width”. “Wide” filters exhibit a larger
invariance to noise, but also a decreased ability to detect small
details. Non-recursive filters, such as the Canny filter, are
realized using filter masks, and thus the execution time increases
for increasing filter width. In contrast, the execution time for
recursive filters does not depend on the filter width. Thus,
arbitrary filter widths are possible using the Deriche, Lanser and
Shen filters without increasing the run time of the operator. The
resulting advantage in speed compared to the Canny operator
naturally increases for larger filter widths. As border treatment,
the recursive operators assume that the images to be zero outside of
the image, while the Canny operator repeats the gray value at the
image's border. The signal-noise-ratio of the filters is
comparable for the following choices of Alpha
:
Alpha('lanser1') = Alpha('deriche1'),
Alpha('deriche2') = Alpha('deriche1') / 2,
Alpha('lanser2') = Alpha('deriche2'),
Alpha('shen') = Alpha('deriche1') / 2,
Alpha('mshen') = Alpha('shen'),
Alpha('canny') = 1.77 / Alpha('deriche1').
The originally proposed recursive filters ('deriche1', 'deriche2',
'shen') return a biased estimate of the amplitude of diagonal
edges. This bias is removed in the corresponding modified version
of the operators ('lanser1', 'lanser2' and 'mshen'), while
maintaining the same execution speed.
For relatively small filter widths (11 x 11), i.e., for Alpha ('lanser2' = 0.5), all filters yield similar results. Only for “wider” filters differences begin to appear: the Shen filters begin to yield qualitatively inferior results. However, they are the fastest of the implemented operators that support arbitrary mask sizes, closely followed by the Deriche operators. The two Sobel filters, which use a fixed mask size of (3 x 3), are faster than the other filters. Of these two, the filter 'sobel_fast' is significantly faster than 'sobel' .
edges_sub_pix
links the edge points into edges by using
an algorithm similar to a hysteresis threshold operation, which is
also used in lines_gauss
. Points with an amplitude
larger than High
are immediately accepted as belonging to
an edge, while points with an amplitude smaller than Low
are rejected. All other points are accepted as edges if they are
connected to accepted edge points (see also lines_gauss
and hysteresis_threshold
).
Because edge extractors are often unable to extract certain
junctions, a mode that tries to extract these missing junctions by
different means can be selected by appending '_junctions'
to the values of Filter
that are described above. This
mode is analogous to the mode for completing junctions that is
available in lines_gauss
.
The edge operator 'sobel_fast' has the same semantics as all the other edge operators. Internally, however, it is based on significantly simplified variants of the individual processing steps (hysteresis thresholding, edge point linking, and extraction of the subpixel edge positions). Therefore, 'sobel_fast' in some cases may return slightly less accurate edge positions and may select different edge parts.
edges_sub_pix
can be executed on OpenCL devices for the filter
types 'canny' and 'sobel_fast' . This will require
up to width*height*29 bytes of pinned memory. Since allocating memory
is an expensive operation, it would make sense to set the pinned memory
cache to at least this size (using set_compute_device_param
for
parameter 'pinned_mem_cache_capacity' , or to disable pinned memory
completely (using set_compute_device_param
for parameter
'alloc_pinned' ), in which case the normal memory cache is
used. Note that the results can vary from the CPU implementation.
Since edges_sub_pix
uses Gauss convolution internally for the
'canny' filter, the same limitations for OpenCL apply as for
derivate_gauss
: Alpha
must be chosen small enough that
the required filter mask is less than 129 pixels in size. Also,
edges_sub_pix
is not available on OpenCL devices for HALCON XL, as
double precision floating point arithmetic would be required, but OpenCL
devices are optimized for single precision arithmetic.
Note that filter operators may return unexpected results if an image with a reduced domain is used as input. Please refer to the chapter Filters.
This operator supports cancelling timeouts and interrupts.
Image
(input_object) singlechannelimage →
object (byte / uint2 / real)
Input image.
Edges
(output_object) xld_cont-array →
object
Extracted edges.
Filter
(input_control) string →
(string)
Edge operator to be applied.
Default value: 'canny'
List of values: 'canny' , 'canny_junctions' , 'deriche1' , 'deriche1_junctions' , 'deriche2' , 'deriche2_junctions' , 'lanser1' , 'lanser1_junctions' , 'lanser2' , 'lanser2_junctions' , 'mshen' , 'mshen_junctions' , 'shen' , 'shen_junctions' , 'sobel' , 'sobel_fast' , 'sobel_junctions'
List of values (for compute devices): 'canny' , 'sobel_fast'
Alpha
(input_control) real →
(real)
Filter parameter: small values result in strong smoothing, and thus less detail (opposite for 'canny').
Default value: 1.0
Suggested values: 0.1, 0.2, 0.3, 0.4, 0.5, 0.7, 0.9, 1.1
Typical range of values: 0.2
≤
Alpha
≤
50.0
Minimum increment: 0.01
Recommended increment: 0.1
Restriction: Alpha > 0.0
Low
(input_control) integer →
(integer / real)
Lower threshold for the hysteresis threshold operation.
Default value: 20
Suggested values: 5, 10, 15, 20, 25, 30, 40
Typical range of values: 1
≤
Low
≤
255
Minimum increment: 1
Recommended increment: 5
Restriction: Low > 0
High
(input_control) integer →
(integer / real)
Upper threshold for the hysteresis threshold operation.
Default value: 40
Suggested values: 10, 15, 20, 25, 30, 40, 50, 60, 70
Typical range of values: 1
≤
High
≤
255
Minimum increment: 1
Recommended increment: 5
Restriction: High > 0 && High >= Low
read_image(Image,'fabrik') edges_sub_pix(Image,Edges,'lanser2',0.5,20,40)
Let A be the number of pixels in the domain of Image
.
Then the runtime complexity is O(A*Alpha) for the Canny
filter and O(A) for the recursive Lanser, Deriche, and Shen
filters.
The amount of temporary memory required is dependent on the height H
of the domain of Image
and the width W of Image
.
Let S = W*H, then edges_sub_pix
requires at least 60*S
bytes of temporary memory during execution for all edge operators
except 'sobel_fast' . For 'sobel_fast' , at least
9*S bytes of temporary memory are required.
edges_sub_pix
returns 2 (H_MSG_TRUE) if all parameters are correct
and no error occurs during execution. If the input is empty the
behavior can be set via
set_system('no_object_result',<Result>)
. If
necessary, an exception is raised.
segment_contours_xld
,
gen_polygons_xld
,
select_shape_xld
sobel_dir
,
frei_dir
,
kirsch_dir
,
prewitt_dir
,
robinson_dir
,
edges_image
info_edges
,
hysteresis_threshold
,
bandpass_image
,
lines_gauss
,
lines_facet
S.Lanser, W.Eckstein: “Eine Modifikation des Deriche-Verfahrens zur
Kantendetektion”; 13. DAGM-Symposium, München; Informatik
Fachberichte 290; Seite 151 - 158; Springer-Verlag; 1991.
S.Lanser: “Detektion von Stufenkanten mittels rekursiver Filter
nach Deriche”; Diplomarbeit; Technische Universität München,
Institut für Informatik, Lehrstuhl Prof. Radig; 1991.
J.Canny: “Finding Edges and Lines in Images”; Report, AI-TR-720;
M.I.T. Artificial Intelligence Lab., Cambridge; 1983.
J.Canny: “A Computational Approach to Edge Detection”; IEEE
Transactions on Pattern Analysis and Machine Intelligence; PAMI-8,
vol. 6; S. 679-698; 1986.
R.Deriche: “Using Canny's Criteria to Derive a Recursively
Implemented Optimal Edge Detector”; International Journal of
Computer Vision; vol. 1, no. 2; S. 167-187; 1987.
R.Deriche: “Optimal Edge Detection Using Recursive Filtering”;
Proc. of the First International Conference on Computer Vision,
London; S. 501-505; 1987.
R.Deriche: “Fast Algorithms for Low-Level Vision”; IEEE
Transactions on Pattern Analysis and Machine Intelligence; PAMI-12,
no. 1; S. 78-87; 1990.
S.Castan, J.Zhao und J.Shen: “Optimal Filter for Edge Detection
Methods and Results”; Proc. of the First European Conference on
Computer Vision, Antibes; Lecture Notes on computer Science;
no. 427; S. 12-17; Springer-Verlag; 1990.
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