Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have an image where in I need to remove the "white" artifacts that do not represent a detected curve. I want to preserve the white pixels which represent the curve but, remove pixel outliers which are far away from the curve. After removing the artifacts, I would like to fit a smooth curve to the points in the image.

This is my image:

white detected curve

The image is a 8-bit grayscale image image with only black and white points. The white pixels in the "curve" are the area of interest and most of them are only a single pixel thick. Some white pixels are connected to each other but, not all of them. Some white pixels are strewn across. I would like to remove these white pixels since they are not contributing to the overall shape because I want to fit a smooth curve to them.

So far, I have tried to do dilation followed by erosion, closing and black hat operations. None of them seem to give me the result that I expect. I also tried to iterate through all points in the image, find the bright points, look in a 3x3 neighborhood around that pixel and set the value to 0 if it did not have more than two neighbors which are equal to itself.

What can I apply in order to achieve my desired result? Also, once I have my final "clean" output, how do I fit a smooth curve to the points in the image?

share|improve this question
    
I think that a dilation followed by a bigger erosion should remove most of the artifacts while keeping the components of the curve. To fit the curve, you may try some Hough voting approach. –  ChronoTrigger Apr 4 '14 at 20:25
    
@ChronoTrigger No, that's worse. The detected surface either completely disappears of has more pixels than necessary which is considered noise. I am looking for a way to preserve the detected edges. Maybe similar to a connected-component approach? –  Eagle Apr 5 '14 at 0:20
    
@ChronoTrigger What is the Hough Voting scheme? Do you have a few links to the documentation/implementation from where I can learn stuff? –  Eagle Apr 5 '14 at 0:26
    

1 Answer 1

I don't know how to fit the curve, it would be nice of you to ask this in another question.


About the noise: This function should do the trick, I've used it to remove noise in a black and wait image. It is a code sample from the book:

Mastering OpenCV with Practical Computer Vision Projects - Daniel Lelis Baggio

I have these includes added on the header where this function was instantiated:

#include  "opencv2/opencv.hpp"
#include <stdio.h>
#include <iostream>
#include <vector>

using namespace cv;
using namespace std;

mask is the image you want to filter, and it removes dots that don't have dots in any 5 pixels around the analysed one... Hope it helps

void removePepperNoise(Mat &mask)
{
// For simplicity, ignore the top & bottom row border.
for (int y=2; y<mask.rows-2; y++) {
    // Get access to each of the 5 rows near this pixel.
    uchar *pThis = mask.ptr(y);
    uchar *pUp1 = mask.ptr(y-1);
    uchar *pUp2 = mask.ptr(y-2);
    uchar *pDown1 = mask.ptr(y+1);
    uchar *pDown2 = mask.ptr(y+2);

    // For simplicity, ignore the left & right row border.
    pThis += 2;
    pUp1 += 2;
    pUp2 += 2;
    pDown1 += 2;
    pDown2 += 2;
    for (int x=2; x<mask.cols-2; x++) {
        uchar v = *pThis;   // Get the current pixel value (either 0 or 255).
        // If the current pixel is black, but all the pixels on the 2-pixel-radius-border are white
        // (ie: it is a small island of black pixels, surrounded by white), then delete that island.
        if (v == 0) {
            bool allAbove = *(pUp2 - 2) && *(pUp2 - 1) && *(pUp2) && *(pUp2 + 1) && *(pUp2 + 2);
            bool allLeft = *(pUp1 - 2) && *(pThis - 2) && *(pDown1 - 2);
            bool allBelow = *(pDown2 - 2) && *(pDown2 - 1) && *(pDown2) && *(pDown2 + 1) && *(pDown2 + 2);
            bool allRight = *(pUp1 + 2) && *(pThis + 2) && *(pDown1 + 2);
            bool surroundings = allAbove && allLeft && allBelow && allRight;
            if (surroundings == true) {
                // Fill the whole 5x5 block as white. Since we know the 5x5 borders
                // are already white, just need to fill the 3x3 inner region.
                *(pUp1 - 1) = 255;
                *(pUp1 + 0) = 255;
                *(pUp1 + 1) = 255;
                *(pThis - 1) = 255;
                *(pThis + 0) = 255;
                *(pThis + 1) = 255;
                *(pDown1 - 1) = 255;
                *(pDown1 + 0) = 255;
                *(pDown1 + 1) = 255;
            }
            // Since we just covered the whole 5x5 block with white, we know the next 2 pixels
            // won't be black, so skip the next 2 pixels on the right.
            pThis += 2;
            pUp1 += 2;
            pUp2 += 2;
            pDown1 += 2;
            pDown2 += 2;
        }
        // Move to the next pixel.
        pThis++;
        pUp1++;
        pUp2++;
        pDown1++;
        pDown2++;
    }
}
share|improve this answer
    
I don't want to remove the white pixels. I want to preserve the structure of the white pixels in the curve but, I want to get rid of those outlier white pixels which are far away from the curve. I'm not sure what your code is trying to do but, I will try and see if it works. –  Eagle Apr 4 '14 at 19:12
    
The code removes single 'black pixels' in a 5x5 block from the image (the time I used it my noise was black). I didn't notice you have island of pixels together the same proportion as in your line. Sorry for the bad approach, it will not solve your problem. –  Electric Goat Apr 7 '14 at 5:53
    
Your code pointed me in the right direction. I had an idea after that to look for pixels across diagonals as shown here: stackoverflow.com/questions/22898881/… . The output looks good when line segments are used to approximate a curve. However, I would ideally like a smooth curve since I cannot get rid of all of the outliers without risking the loss of a bunch of points on the detected curve. I have to tradeoff now somehow I guess unless I can actually fit a curve properly. –  Eagle Apr 7 '14 at 6:08
    
If you are able to find adjacent points centroids you could try a polynomial regression (actually I think it would work with the image you already have just knowing the white pixel positions). The GNU Scientific Library can do it. (rosettacode.org/wiki/Polynomial_regression#C) –  Electric Goat Apr 7 '14 at 7:48
    
I don't understand what you mean by "adjacent point centroids"? Do you mean points which have white pixels to its left and right? –  Eagle Apr 8 '14 at 19:02

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.