I´m trying to find the corners on a image, I don´t need the contours, only the 4 corners. I will change the perspective using 4 corners.

I´m using Opencv, but I need to know the steps to find the corners and what function I will use.

My images will be like this:(without red points, I will paint the points after) enter image description here


After suggested steps, I writed the code: (Note: I´m not using pure OpenCv, I´m using javaCV, but the logic it´s the same).

// Load two images and allocate other structures (I´m using other image)
    IplImage colored = cvLoadImage(

enter image description here

    IplImage gray = cvCreateImage(cvGetSize(colored), IPL_DEPTH_8U, 1);
    IplImage smooth = cvCreateImage(cvGetSize(colored), IPL_DEPTH_8U, 1);

    //Step 1 - Convert from RGB to grayscale (cvCvtColor)
    cvCvtColor(colored, gray, CV_RGB2GRAY);

enter image description here

    //2 Smooth (cvSmooth)
    cvSmooth( gray, smooth, CV_BLUR, 9, 9, 2, 2); 

enter image description here

    //3 - cvThreshold  - What values?
    cvThreshold(gray,gray, 155, 255, CV_THRESH_BINARY);

enter image description here

    //4 - Detect edges (cvCanny) -What values?
    int N = 7;
    int aperature_size = N;
    double lowThresh = 20;
    double highThresh = 40;     
    cvCanny( gray, gray, lowThresh*N*N, highThresh*N*N, aperature_size );   

enter image description here

    //5 - Find contours (cvFindContours)
    int total = 0;
    CvSeq contour2 = new CvSeq(null);
    CvMemStorage storage2 = cvCreateMemStorage(0);
    CvMemStorage storageHull = cvCreateMemStorage(0);
    total = cvFindContours(gray, storage2, contour2, Loader.sizeof(CvContour.class), CV_RETR_CCOMP, CV_CHAIN_APPROX_NONE);
    if(total > 1){
          while (contour2 != null && !contour2.isNull()) {
              if (contour2.elem_size() > 0) {
                //6 - Approximate contours with linear features (cvApproxPoly)
                  CvSeq points = cvApproxPoly(contour2,Loader.sizeof(CvContour.class), storage2, CV_POLY_APPROX_DP,cvContourPerimeter(contour2)*0.005, 0);
                  cvDrawContours(gray, points,CvScalar.BLUE, CvScalar.BLUE, -1, 1, CV_AA);

              contour2 = contour2.h_next();


enter image description here

So, I want to find the cornes, but I don´t know how to use corners function like cvCornerHarris and others.

  • 4
    OpenCV's "corner" functions don't find corners in the way you're thinking of -- roughly speaking, they find areas with significant horizontal and vertical variation. The goal of the corner functions in OpenCV is to find distinctive parts of the image that will be useful for visual tracking, which is not necessarily what we commonly think of as corners. Sep 2, 2011 at 21:29
  • The exact code at stackoverflow.com/a/14368605/1832154 (except the resizing part, since your image is small enough already) gives i.imgur.com/hMdAlHX.png
    – mmgp
    Jan 31, 2013 at 3:33
  • Finding a global threshold and using "contour" (blob) detection for this kind of application is not a robust approach. Scanning for edges horizontally and vertically from the image edges inwards would be a reasonable start if your application is to find a (distorted) rectangle of paper.
    – Rethunk
    May 29, 2018 at 10:53
  • @Ricardo Can you please provide the final working code? Nov 7, 2020 at 4:35

5 Answers 5


First, check out /samples/c/squares.c in your OpenCV distribution. This example provides a square detector, and it should be a pretty good start on how to detect corner-like features. Then, take a look at OpenCV's feature-oriented functions like cvCornerHarris() and cvGoodFeaturesToTrack().

The above methods can return many corner-like features - most will not be the "true corners" you are looking for. In my application, I had to detect squares that had been rotated or skewed (due to perspective). My detection pipeline consisted of:

  1. Convert from RGB to grayscale (cvCvtColor)
  2. Smooth (cvSmooth)
  3. Threshold (cvThreshold)
  4. Detect edges (cvCanny)
  5. Find contours (cvFindContours)
  6. Approximate contours with linear features (cvApproxPoly)
  7. Find "rectangles" which were structures that: had polygonalized contours possessing 4 points, were of sufficient area, had adjacent edges were ~90 degrees, had distance between "opposite" vertices was of sufficient size, etc.

Step 7 was necessary because a slightly noisy image can yield many structures that appear rectangular after polygonalization. In my application, I also had to deal with square-like structures that appeared within, or overlapped the desired square. I found the contour's area property and center of gravity to be helpful in discerning the proper rectangle.

  • I need a little help with step 7, how to use cvCornerHarris, with my example, see the edited post, can you help me? Sep 2, 2011 at 20:00
  • 1
    Is cvSmooth something like a Gaussian blur? Do you dilate the result from cvCanny? How do you approximate contours with, let's say 5 corners (deformated square because of shadows etc.) or suqares with a little ridge. Your approach is pretty much what I want to do, but I am struggeling very hard. Can you provide some code examples? Would be very helpful.
    – sschrass
    Mar 12, 2012 at 11:33

At a first glance, for a human eye there are 4 corners. But in computer vision, a corner is considered to be a point that has large gradient change in intensity across its neighborhood. The neighborhood can be a 4 pixel neighborhood or an 8 pixel neighborhood.

enter image description here

In the equation provided to find the gradient of intensity, it has been considered for 4-pixel neighborhood SEE DOCUMENTATION.

Here is my approach for the image in question. I have the code in python as well:

path = r'C:\Users\selwyn77\Desktop\Stack\corner'
filename = 'env.jpg'

img = cv2.imread(os.path.join(path, filename))
gray = cv2.cvtColor(img,cv2.COLOR_BGR2GRAY)    #--- convert to grayscale 

It is a good choice to always blur the image to remove less possible gradient changes and preserve the more intense ones. I opted to choose the bilateral filter which unlike the Gaussian filter doesn't blur all the pixels in the neighborhood. It rather blurs pixels which has similar pixel intensity to that of the central pixel. In short it preserves edges/corners of high gradient change but blurs regions that have minimal gradient changes.

bi = cv2.bilateralFilter(gray, 5, 75, 75)

enter image description here

To a human it is not so much of a difference compared to the original image. But it does matter. Now finding possible corners:

dst = cv2.cornerHarris(bi, 2, 3, 0.04)

dst returns an array (the same 2D shape of the image) with eigen values obtained from the final equation mentioned HERE.

Now a threshold has to be applied to select those corners beyond a certain value. I will use the one in the documentation:

#--- create a black image to see where those corners occur ---
mask = np.zeros_like(gray)

#--- applying a threshold and turning those pixels above the threshold to white ---           
mask[dst>0.01*dst.max()] = 255
cv2.imshow('mask', mask)

enter image description here

The white pixels are regions of possible corners. You can find many corners neighboring each other.

To draw the selected corners on the image:

img[dst > 0.01 * dst.max()] = [0, 0, 255]   #--- [0, 0, 255] --> Red ---
cv2.imshow('dst', img)

enter image description here

(Red colored pixels are the corners, not so visible)

In order to get an array of all pixels with corners:

coordinates = np.argwhere(mask)


Variable coor is an array of arrays. Converting it to list of lists

coor_list = [l.tolist() for l in list(coor)]

Converting the above to list of tuples

coor_tuples = [tuple(l) for l in coor_list]

I have an easy and rather naive way to find the 4 corners. I simply calculated the distance of each corner to every other corner. I preserved those corners whose distance exceeded a certain threshold.

Here is the code:

thresh = 50

def distance(pt1, pt2):
    (x1, y1), (x2, y2) = pt1, pt2
    dist = math.sqrt( (x2 - x1)**2 + (y2 - y1)**2 )
    return dist

coor_tuples_copy = coor_tuples

i = 1    
for pt1 in coor_tuples:

    print(' I :', i)
    for pt2 in coor_tuples[i::1]:
        print(pt1, pt2)
        print('Distance :', distance(pt1, pt2))
        if(distance(pt1, pt2) < thresh):

Prior to running the snippet above coor_tuples had all corner points: [(4, 42), (4, 43), (5, 43), (5, 44), (6, 44), (7, 219), (133, 36), (133, 37), (133, 38), (134, 37), (135, 224), (135, 225), (136, 225), (136, 226), (137, 225), (137, 226), (137, 227), (138, 226)]

After running the snippet I was left with 4 corners:

[(4, 42), (7, 219), (133, 36), (135, 224)]


Now all you have to do is just mark these 4 points on a copy of the original image.

img2 = img.copy()
for pt in coor_tuples:
    cv2.circle(img2, tuple(reversed(pt)), 3, (0, 0, 255), -1)
cv2.imshow('Image with 4 corners', img2) 

enter image description here

  • Thank you! Last step: how would you extract only 4 points as corners (useful for further deskewing / perspective correction)? Do you need to use an algorithm to find clusters in the many points? ("The white pixels are regions of possible corners. You can find many corners neighboring each other.") Could you add an example?
    – Basj
    May 28, 2018 at 8:29
  • Thanks a lot @JeruLuke!
    – Basj
    May 29, 2018 at 8:15
  • Can you please help me to translate these example codes into c++ language?
    – noobie
    Oct 7, 2021 at 8:10
  • @noobie I don't have the code in C++
    – Jeru Luke
    Oct 8, 2021 at 10:20

Here's an implementation using cv2.goodFeaturesToTrack() to detect corners. The approach is

  • Convert image to grayscale
  • Perform canny edge detection
  • Detect corners
  • Optionally perform 4-point perspective transform to get top-down view of image

Using this starting image,

enter image description here

After converting to grayscale, we perform canny edge detection

enter image description here

Now that we have a decent binary image, we can use cv2.goodFeaturesToTrack()

corners = cv2.goodFeaturesToTrack(canny, 4, 0.5, 50)

For the parameters, we give it the canny image, set the maximum number of corners to 4 (maxCorners), use a minimum accepted quality of 0.5 (qualityLevel), and set the minimum possible Euclidean distance between the returned corners to 50 (minDistance). Here's the result

enter image description here

Now that we have identified the corners, we can perform a 4-point perspective transform to obtain a top-down view of the object. We first order the points clockwise then draw the result onto a mask.

Note: We could have just found contours on the Canny image instead of doing this step to create the mask, but pretend we only had the 4 corner points to work with

enter image description here

Next we find contours on this mask and filter using cv2.arcLength() and cv2.approxPolyDP(). The idea is that if the contour has 4 points, then it must be our object. Once we have this contour, we perform a perspective transform

enter image description here

Finally we rotate the image depending on the desired orientation. Here's the result

enter image description here

Code for only detecting corners

import cv2

image = cv2.imread('1.png')
gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
canny = cv2.Canny(gray, 120, 255, 1)

corners = cv2.goodFeaturesToTrack(canny,4,0.5,50)

for corner in corners:
    x,y = corner.ravel()

cv2.imshow('canny', canny)
cv2.imshow('image', image)

Code for detecting corners and performing perspective transform

import cv2
import numpy as np

def rotate_image(image, angle):
    # Grab the dimensions of the image and then determine the center
    (h, w) = image.shape[:2]
    (cX, cY) = (w / 2, h / 2)

    # grab the rotation matrix (applying the negative of the
    # angle to rotate clockwise), then grab the sine and cosine
    # (i.e., the rotation components of the matrix)
    M = cv2.getRotationMatrix2D((cX, cY), -angle, 1.0)
    cos = np.abs(M[0, 0])
    sin = np.abs(M[0, 1])

    # Compute the new bounding dimensions of the image
    nW = int((h * sin) + (w * cos))
    nH = int((h * cos) + (w * sin))

    # Adjust the rotation matrix to take into account translation
    M[0, 2] += (nW / 2) - cX
    M[1, 2] += (nH / 2) - cY

    # Perform the actual rotation and return the image
    return cv2.warpAffine(image, M, (nW, nH))

def order_points_clockwise(pts):
    # sort the points based on their x-coordinates
    xSorted = pts[np.argsort(pts[:, 0]), :]

    # grab the left-most and right-most points from the sorted
    # x-roodinate points
    leftMost = xSorted[:2, :]
    rightMost = xSorted[2:, :]

    # now, sort the left-most coordinates according to their
    # y-coordinates so we can grab the top-left and bottom-left
    # points, respectively
    leftMost = leftMost[np.argsort(leftMost[:, 1]), :]
    (tl, bl) = leftMost

    # now, sort the right-most coordinates according to their
    # y-coordinates so we can grab the top-right and bottom-right
    # points, respectively
    rightMost = rightMost[np.argsort(rightMost[:, 1]), :]
    (tr, br) = rightMost

    # return the coordinates in top-left, top-right,
    # bottom-right, and bottom-left order
    return np.array([tl, tr, br, bl], dtype="int32")

def perspective_transform(image, corners):
    def order_corner_points(corners):
        # Separate corners into individual points
        # Index 0 - top-right
        #       1 - top-left
        #       2 - bottom-left
        #       3 - bottom-right
        corners = [(corner[0][0], corner[0][1]) for corner in corners]
        top_r, top_l, bottom_l, bottom_r = corners[0], corners[1], corners[2], corners[3]
        return (top_l, top_r, bottom_r, bottom_l)

    # Order points in clockwise order
    ordered_corners = order_corner_points(corners)
    top_l, top_r, bottom_r, bottom_l = ordered_corners

    # Determine width of new image which is the max distance between 
    # (bottom right and bottom left) or (top right and top left) x-coordinates
    width_A = np.sqrt(((bottom_r[0] - bottom_l[0]) ** 2) + ((bottom_r[1] - bottom_l[1]) ** 2))
    width_B = np.sqrt(((top_r[0] - top_l[0]) ** 2) + ((top_r[1] - top_l[1]) ** 2))
    width = max(int(width_A), int(width_B))

    # Determine height of new image which is the max distance between 
    # (top right and bottom right) or (top left and bottom left) y-coordinates
    height_A = np.sqrt(((top_r[0] - bottom_r[0]) ** 2) + ((top_r[1] - bottom_r[1]) ** 2))
    height_B = np.sqrt(((top_l[0] - bottom_l[0]) ** 2) + ((top_l[1] - bottom_l[1]) ** 2))
    height = max(int(height_A), int(height_B))

    # Construct new points to obtain top-down view of image in 
    # top_r, top_l, bottom_l, bottom_r order
    dimensions = np.array([[0, 0], [width - 1, 0], [width - 1, height - 1], 
                    [0, height - 1]], dtype = "float32")

    # Convert to Numpy format
    ordered_corners = np.array(ordered_corners, dtype="float32")

    # Find perspective transform matrix
    matrix = cv2.getPerspectiveTransform(ordered_corners, dimensions)

    # Return the transformed image
    return cv2.warpPerspective(image, matrix, (width, height))

image = cv2.imread('1.png')
original = image.copy()
gray = cv2.cvtColor(image, cv2.COLOR_BGR2GRAY)
canny = cv2.Canny(gray, 120, 255, 1)

corners = cv2.goodFeaturesToTrack(canny,4,0.5,50)

c_list = []
for corner in corners:
    x,y = corner.ravel()
    c_list.append([int(x), int(y)])

corner_points = np.array([c_list[0], c_list[1], c_list[2], c_list[3]])
ordered_corner_points = order_points_clockwise(corner_points)
mask = np.zeros(image.shape, dtype=np.uint8)
cv2.fillPoly(mask, [ordered_corner_points], (255,255,255))

mask = cv2.cvtColor(mask, cv2.COLOR_BGR2GRAY)
cnts = cv2.findContours(mask, cv2.RETR_EXTERNAL, cv2.CHAIN_APPROX_SIMPLE)
cnts = cnts[0] if len(cnts) == 2 else cnts[1]

for c in cnts:
    peri = cv2.arcLength(c, True)
    approx = cv2.approxPolyDP(c, 0.015 * peri, True)
    if len(approx) == 4:
        transformed = perspective_transform(original, approx)

result = rotate_image(transformed, -90)

cv2.imshow('canny', canny)
cv2.imshow('image', image)
cv2.imshow('mask', mask)
cv2.imshow('transformed', transformed)
cv2.imshow('result', result)
  1. find contours with RETR_EXTERNAL option.(gray -> gaussian filter -> canny edge -> find contour)
  2. find the largest size contour -> this will be the edge of the rectangle
  3. find corners with little calculation

    Mat m;//image file
    findContours(m, contours_, hierachy_, RETR_EXTERNAL);
    auto it = max_element(contours_.begin(), contours_.end(),
        [](const vector<Point> &a, const vector<Point> &b) {
            return a.size() < b.size(); });
    Point2f xy[4] = {{9000,9000}, {0, 1000}, {1000, 0}, {0,0}};
    for(auto &[x, y] : *it) {
        if(x + y < xy[0].x + xy[0].y) xy[0] = {x, y};
        if(x - y > xy[1].x - xy[1].y) xy[1] = {x, y};
        if(y - x > xy[2].y - xy[2].x) xy[2] = {x, y};
        if(x + y > xy[3].x + xy[3].y) xy[3] = {x, y};

xy[4] will be the four corners. I was able to extract four corners this way.


Apply houghlines to the canny image - you will get a list of points apply convex hull to this set of points

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