I'm trying to segment business cards and split them by background color to treat them as different regions of interest.

For example a card of this sort: Sample business card

should be able to be to be split into two images as there are 2 background colors. Are there any suggestions on how to tackle this? I've tried doing some contour analysis which didn't turn out too successful.

Other example cards: enter image description here

This card should give 3 segmentations, as there are three portions even though it's only 2 colors (though 2 colors will be okay).

enter image description here

The above card should give just one segmentation as it is just one background color.

I'm not trying to think of gradient backgrounds just yet.


It depends on how the other cards look, but if the images all are in that great quality, it should not be too hard.

In the example you posted, you could just collect the colors of the border pixels (most left column, most right column, first row, last row) and treat what you find as possible background colors. Perhaps check if there are enough pixels with roughly the same color. You need some kind of distance measuring. One easy solution is to just use the euclidean distance in RGB color space.

A more generic solution would be to find clusters in the color histograms of the whole image and treat every color (again with tolerance) that has more than x% of the overall pixel amount as a background color. But what you define as background depends on what you want to achieve and how your images look.

If you need further suggestions, you could post more images and tag what parts of the images you want to be detected as a background color and what parst not.


Edit: Your two new images also show the same pattern. Background colors occupy a big part of the image, there is no noise and there are no color gradients. So a simple approach could look like the following:

If you have examples that do not work with this approach, just post them.

  • I've added a few more example cards. Can you also relate your answer more to OpenCV if possible? – SalGad Jan 9 '13 at 17:40
  • I have edited my answer according to the new information. – Tobias Hermann Jan 9 '13 at 20:32
  • Thanks @Dobi, I will try this out and let you know :) – SalGad Jan 10 '13 at 13:26
  • Do you have any advice on what kind of threshold to use? I'm racking my mind on how to isolate each peak on the histogram on the image so I can get contours relating just to that peak – SalGad Jan 11 '13 at 7:58
  • If your images are all as clear as your examples, your histogram peaks will be very narrow and high. Just experiment with it. My first guess would be: Use 16 bins per dimension in your histogram. Use every bin (of your 16^3) with its value higher than 0.3*number_of_pixels_in_image as bg color, and use a threshold with a tolerance of 16 color values difference for the segmentation of it. – Tobias Hermann Jan 11 '13 at 12:38

As an approach for also finding backgrounds with color gradients in them, one could use canny. The following code (yes, not android, I know, but the result should be the same if you port it) works fine with the three example images you posted so far. If you have other images, that do not work with this, please let me know.

#include <opencv2/opencv.hpp>

using namespace cv;
using namespace std;

Mat src;
Mat src_gray;
int canny_thresh = 100;
int max_canny_thresh = 255;
int size_per_mill = 120;
int max_size_per_mill = 1000;
RNG rng(12345);

bool cmp_contour_area_less(const vector<Point>& lhs, const vector<Point>& rhs)
    return contourArea(lhs) < contourArea(rhs);

void Segment()
    Mat canny_output;
    vector<vector<Point> > contours;
    vector<Vec4i> hierarchy;

    Canny(src_gray, canny_output, canny_thresh, canny_thresh*2, 3);

    // Draw rectangle around canny image to also get regions touching the edges.
    rectangle(canny_output, Point(1, 1), Point(src.cols-2, src.rows-2), Scalar(255));
    namedWindow("Canny", CV_WINDOW_AUTOSIZE);
    imshow("Canny", canny_output);

    // Find the contours.
    findContours(canny_output, contours, hierarchy, CV_RETR_TREE, CV_CHAIN_APPROX_SIMPLE, Point(0, 0));

    // Remove largest Contour, because it represents always the whole image.
    sort(contours.begin(), contours.end(), cmp_contour_area_less);
    reverse(contours.begin(), contours.end());

    // Maximum contour size.
    int image_pixels(src.cols * src.rows);
    cout << "image_pixels: " << image_pixels << "\n";

    // Filter the contours, leaving just large enough ones.
    vector<vector<Point> > background_contours;
    for(size_t i(0); i < contours.size(); ++i)
        double area(contourArea(contours[i]));
        double min_size((size_per_mill / 1000.0) * image_pixels);
        if (area >= min_size)
            cout << "Background contour " << i << ") area: " << area << "\n";

    // Draw large contours.
    Mat drawing = Mat::zeros(canny_output.size(), CV_8UC3);
    for(size_t i(0); i < background_contours.size(); ++i)
        Scalar color = Scalar(rng.uniform(0, 255), rng.uniform(0,255), rng.uniform(0,255));
        drawContours(drawing, background_contours, i, color, 1, 8, hierarchy, 0, Point());

    namedWindow("Contours", CV_WINDOW_AUTOSIZE);
    imshow("Contours", drawing);

void size_callback(int, void*)

void thresh_callback(int, void*)

int main(int argc, char* argv[])
    if (argc != 2)
        cout << "Please provide an image file.\n";
        return -1;

    src = imread(argv[1]);

    cvtColor(src, src_gray, CV_BGR2GRAY);
    blur(src_gray, src_gray, Size(3,3));

    namedWindow("Source", CV_WINDOW_AUTOSIZE);
    imshow("Source", src);

    if (!src.data)
        cout << "Unable to load " << argv[1] << ".\n";
        return -2;

    createTrackbar("Canny thresh:", "Source", &canny_thresh, max_canny_thresh, thresh_callback);
    createTrackbar("Size thresh:", "Source", &size_per_mill, max_size_per_mill, thresh_callback);


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