pouringpouringPouringPouringPouringpouring regards the input image as a “mountain range.”
Larger gray values correspond to mountain peaks, while smaller gray
values correspond to valley bottoms. pouringpouringPouringPouringPouringpouring segments
the input image in several steps. First, the local maxima are
extracted, i.e., pixels which either alone or in the form of an
extended plateau have larger gray values than their immediate
neighbors (in 4-neighborhood). In the next step, the maxima thus
found are the starting points for an expansion until “valley
bottoms” are reached. The expansion is done as long as there are
chains of pixels in which the gray value becomes smaller (like water
running downhill from the maxima in all directions). Again, the
4-neighborhood is used, but with a weaker condition (smaller or
equal). This means that points at valley bottoms may belong to
more than one maximum. These areas are at first not assigned to a
region, but rather are split among all competing segments in the
last step. The split is done by a uniform expansion of all involved
segments, until all ambiguous pixels were assigned. The parameter
ModeModeModeModemodemode determines which steps are executed. The following
values are possible:
'all'
This is the normal mode of operation. All steps of the
segmentation are performed. The regions are assigned to maxima,
and overlapping regions are split.
'maxima'
The segmentation only extracts the local maxima of the input
image. No corresponding regions are extracted.
'regions'
The segmentation extracts the local maxima of the input image
and the corresponding regions, which are uniquely determined.
Areas that were assigned to more than one maximum are not
split.
List of values: 'all'"all""all""all""all""all", 'maxima'"maxima""maxima""maxima""maxima""maxima", 'regions'"regions""regions""regions""regions""regions"
Typical range of values: 0
≤
MaxGrayMaxGrayMaxGrayMaxGraymaxGraymax_gray
≤
255 (lin)
Minimum increment: 1
Recommended increment: 10
Restriction: MaxGray <= 255 && MaxGray > MinGray
Example (HDevelop)
* Segment a filtered image
read_image(Image,'particle')
mean_image(Image,Mean,11,11)
pouring(Mean,Seg,'all',0,255)
dev_display(Mean)
dev_set_colored(12)
dev_display(Seg)
* Segment an image while masking the dark background
read_image(Image,'particle')
mean_image(Image,ImageMean,15,15)
pouring(Mean,Seg,'all',90,255)
dev_display(Mean)
dev_set_colored(12)
dev_display(Seg)
Example (C)
/* Segmentation of a filtered image */
read_image(&Image,"br2");
mean_image(Image,&Mean,11,11);
pouring(Mean,&Seg,"all",0,255);
disp_image(Mean,WindowHandle);
set_colored(WindowHandle,12);
disp_region(Seg,WindowHandle);
/* Segmentation of an image with masking of a dark backround */
read_image(&Image,"hand");
mean_image(Image,&Mean,15,15);
pouring(Mean,&Seg,"all",40,255);
disp_image(Mean,WindowHandle);
set_colored(WindowHandle,12);
disp_region(Seg,WindowHandle);
Example (C++)
#include "HIOStream.h"
#if !defined(USE_IOSTREAM_H)
using namespace std;
#endif
#include "HalconCpp.h"
using namespace Halcon;
int main (int argc, char *argv[])
{
HImage img1 ("br2"),
img2 ("hand"),
img3 ("monkey"),
texture,
testreg;
HWindow w1, w2, w3;
HRegion region;
HRegionArray seg;
w1.SetColored (12); img1.Display (w1);
w2.SetColored (12); img2.Display (w2);
w3.SetColored (12); img3.Display (w3);
cout << "Smoothing of images 1 and 2 ..." << endl;
HImage mean1 = img1.MeanImage (11, 11);
HImage mean2 = img2.MeanImage (15, 15);
cout << "Full segmentation of images ... " << endl;
seg = mean1.Pouring ("all", 0, 255);
seg.Display (w1);
cout << "Segmentation with: a) masked background " << endl;
cout << " b) intersection " << endl;
seg = mean2.Pouring ("regions", 40, 255);
seg.Display (w2);
cout << "Segmentation in 2d-histogram" << endl;
cout << "Draw region with the mouse: " << endl;
region = w3.DrawRegion ();
texture = img3.TextureLaws ("el", 2, 5);
testreg = texture.ReduceDomain (region);
histo = testreg.Histo2dim (texture, region);
seg = histo.Pouring ("all", 0, 255);
seg.Display (w3);
w3.Click ();
return (0);
}
Example (HDevelop)
* Segment a filtered image
read_image(Image,'particle')
mean_image(Image,Mean,11,11)
pouring(Mean,Seg,'all',0,255)
dev_display(Mean)
dev_set_colored(12)
dev_display(Seg)
* Segment an image while masking the dark background
read_image(Image,'particle')
mean_image(Image,ImageMean,15,15)
pouring(Mean,Seg,'all',90,255)
dev_display(Mean)
dev_set_colored(12)
dev_display(Seg)
Example (HDevelop)
* Segment a filtered image
read_image(Image,'particle')
mean_image(Image,Mean,11,11)
pouring(Mean,Seg,'all',0,255)
dev_display(Mean)
dev_set_colored(12)
dev_display(Seg)
* Segment an image while masking the dark background
read_image(Image,'particle')
mean_image(Image,ImageMean,15,15)
pouring(Mean,Seg,'all',90,255)
dev_display(Mean)
dev_set_colored(12)
dev_display(Seg)
Complexity
Let be the number of pixels in the input image and
be the number of found segments, where the enclosing rectangle of the
segment contains pixels. Furthermore, let
be the number of chords in segment .
Then the runtime complexity is
Result
pouringpouringPouringPouringPouringpouring usually returns the value TRUE. If necessary,
an exception is raised.