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I have an image that looks like this:

original

and I want to find the edges of the dark part so like this (the red lines are what I am looking for):

required

I have tried a few approaches and none have worked so I am hoping there is an emgu guru out there willing to help me...

Approach 1

  • Convert the image to grayscale
  • Remove noise and invert
  • Remove anything that is not really bright
  • Get the canny and the polygons

Code for this (I know that I should be disposing of things properly but I am keeping the code short):

var orig = new Image<Bgr, byte>(inFile);

var contours = orig
    .Convert<Gray, byte>()
    .PyrDown()
    .PyrUp()
    .Not()
    .InRange(new Gray(190), new Gray(255))
    .Canny(new Gray(190), new Gray(255))
    .FindContours(CHAIN_APPROX_METHOD.CV_CHAIN_APPROX_SIMPLE,
                  RETR_TYPE.CV_RETR_TREE);

var output = new Image<Gray, byte>(orig.Size);    
for (; contours != null; contours = contours.HNext)
{
    var poly = contours.ApproxPoly(contours.Perimeter*0.05,
                                   contours.Storage);
    output.Draw(poly, new Gray(255), 1);
}
output.Save(outFile);

This is the result:

approach 1 result

Approach 2

  • Convert the image to grayscale
  • Remove noise and invert
  • Remove anything that is not really bright
  • Get the canny and then lines

Code for this:

var orig = new Image<Bgr, byte>(inFile);

var linesegs = orig
    .Convert<Gray, byte>()
    .PyrDown()
    .PyrUp()
    .Not()
    .InRange(new Gray(190), new Gray(255))
    .Canny(new Gray(190), new Gray(255))
    .HoughLinesBinary(
        1,
        Math.PI/45.0,
        20,
        30,
        10
    )[0];

var output = new Image<Gray, byte>(orig.Size);    
foreach (var l in linesegs)
{
    output.Draw(l, new Gray(255), 1);
}
output.Save(outFile);

This is the result:

approach 2 result

Notes

I have tried adjusting all the parameters on those two approaches and adding smoothing but I can never get the simple edges that I need because, I suppose, the darker region is not a solid colour.

I have also tried dilating and eroding but the parameters I have to put in for those are so high to get a single colour that I end up including some of the grey stuff on the right and lose accuracy.

share|improve this question
    
Will this image always look like this? You can convert it to one dimensional image. This should remove some of the noise. If you need solution in 2d try cvAdaptiveThreshold with correct parameters you should be able to tune out the noise. –  Banthar Jun 14 '12 at 13:11
    
Thanks but it is not always exactly like this - sometimes it will be really black in the middle (so less spotty) and sometimes less so (although I am showing you an example that is near the worst it gets). I tried adaptive threshold but at best I got an image that contains a lot of white dots for the part in the middle that when converted to a canny gets the kind of contours you see for approach 1. I tried dilating and eroding the binary image from the adaptive threshold and that did improve it so that I could get a solid region sometimes but it is not reliable. –  kmp Jun 14 '12 at 13:34

1 Answer 1

up vote 17 down vote accepted

Yes, it's possible, and here is how you could do it:

  • Change the contrast of the image to make the lighter part disappear:

enter image description here

  • Then, convert it to HSV to perform a threshold operation on the Saturation channel:

enter image description here

  • And execute erode & dilate operations to get rid of the noises:

enter image description here

At this point you'll have the result you were looking for. For testing purposes, at the end I execute the bounding box technique to show how to detect the beggining and the end of the area of interest:

enter image description here

I didn't have the time to tweak the parameters and make a perfect detection, but I'm sure you can figure it out. This answer provides a roadmap for achieving that!

This is the C++ code I came up with, I trust you are capable of converting it to C#:

#include <cv.h>
#include <highgui.h>

int main(int argc, char* argv[])
{
    cv::Mat image = cv::imread(argv[1]);
    cv::Mat new_image = cv::Mat::zeros(image.size(), image.type());

    /* Change contrast: new_image(i,j) = alpha*image(i,j) + beta */

    double alpha = 1.8;     // [1.0-3.0]
    int beta = 100;         // [0-100]
    for (int y = 0; y < image.rows; y++)
    { 
        for (int x = 0; x < image.cols; x++)
        { 
        for (int c = 0; c < 3; c++)
        {
            new_image.at<cv::Vec3b>(y,x)[c] = 
            cv::saturate_cast<uchar>(alpha * (image.at<cv::Vec3b>(y,x)[c]) + beta);
        }
        }
    }
    cv::imshow("contrast", new_image);

    /* Convert RGB Mat into HSV color space */

    cv::Mat hsv;
    cv::cvtColor(new_image, hsv, CV_BGR2HSV);
    std::vector<cv::Mat> v;
    cv::split(hsv,v);

    // Perform threshold on the S channel of hSv    
    int thres = 15;
    cv::threshold(v[1], v[1], thres, 255, cv::THRESH_BINARY_INV);
    cv::imshow("saturation", v[1]);

    /* Erode & Dilate */

    int erosion_size = 6;   
    cv::Mat element = cv::getStructuringElement(cv::MORPH_CROSS,
                          cv::Size(2 * erosion_size + 1, 2 * erosion_size + 1), 
                          cv::Point(erosion_size, erosion_size) );
    cv::erode(v[1], v[1], element);
    cv::dilate(v[1], v[1], element);    
    cv::imshow("binary", v[1]);

    /* Bounding box */

    // Invert colors
    cv::bitwise_not(v[1], v[1]);

    // Store the set of points in the image before assembling the bounding box
    std::vector<cv::Point> points;
    cv::Mat_<uchar>::iterator it = v[1].begin<uchar>();
    cv::Mat_<uchar>::iterator end = v[1].end<uchar>();
    for (; it != end; ++it)
    {
        if (*it) points.push_back(it.pos());
    }    

    // Compute minimal bounding box
    cv::RotatedRect box = cv::minAreaRect(cv::Mat(points));

    // Draw bounding box in the original image (debug purposes)
    cv::Point2f vertices[4];
    box.points(vertices);
    for (int i = 0; i < 4; ++i)
    {
        cv::line(image, vertices[i], vertices[(i + 1) % 4], cv::Scalar(0, 255, 0), 2, CV_AA);
    }

    cv::imshow("box", image);    
    cvWaitKey(0);

    return 0;
}
share|improve this answer
6  
+1 - good answer. –  Abid Rahman K Jun 14 '12 at 15:05
1  
Awesome answer thanks! Converted it to c# and it worked a treat. –  kmp Jun 15 '12 at 7:59
    
Nice answer, buddy. –  Fukuzawa Yukio Apr 3 '13 at 3:47

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