4

I am able to undistort RGB image successfully.

Now, I am working on directly undistort I420 data, instead of first converting it to RGB.

Below are the steps I followed after camera calibration.

K = cv::Matx33d(541.2152931632737, 0.0, 661.7479652584254,
                0.0, 541.0606969363056, 317.4524205037745,
                0.0,               0.0,               1.0);
D = cv::Vec4d(-0.042166406281296365, -0.001223961942208027, -0.0017036710622692108, 0.00023929900459453295);
newSize = cv::Size(3400, 1940);
cv::Matx33d new_K;
cv::fisheye::estimateNewCameraMatrixForUndistortRectify(K, D, cv::Size(W, H), cv::Mat::eye(3, 3, CV_64F), new_K, 1, newSize);    // W,H are the distorted image size
cv::fisheye::initUndistortRectifyMap(K, D, cv::Mat::eye(3, 3, CV_64F), new_K, newSize, CV_16SC2, mapx, mapy);

cv::remap(src, dst, mapx, mapy, cv::INTER_LINEAR);

Above code is giving me undistorted image successfully.

Now I want to undistort I420 data. So, now my src will be an I420/YV12 data. How can I undistort an I420 data, without converting it first to RGB?

By the way I420 is an image format with only 1 channel(unlike 3 channels in RGB). It has height = 1.5*image height. Its width is equal to image width.

Below code is to convert I420 to BGR

cvtColor(src, BGR, CV_YUV2BGR_I420, 3);

BGR - pixel arrangement BGR I420 - pixel arrangement I

5

The most efficient solution is resizing mapx and mapy and applying shrunk maps on down-sampled U and V channels:

  • Shrink mapx and mapy by a factor of x2 in each axis - create smaller maps matrices.
  • Divide all elements of shrank maps by 2 (applies mapping lower resolution image).
  • Apply mapx and mapy on Y color channel.
  • Apply shrunk_mapx and shrunk_mapy on down-sampled U and V color channels.

Here is a Python OpenCV sample code (please read the comments):

import cv2 as cv
import numpy as np

# For the example, read Y, U and V as separate images.
srcY = cv.imread('DistortedChessBoardY.png', cv.IMREAD_GRAYSCALE) #  Y color channel (1280x720)
srcU = cv.imread('DistortedChessBoardU.png', cv.IMREAD_GRAYSCALE) #  U color channel (640x360)
srcV = cv.imread('DistortedChessBoardV.png', cv.IMREAD_GRAYSCALE) #  V color channel (640x360)

H, W = srcY.shape[0], srcY.shape[1]

K = np.array([[541.2152931632737, 0.0, 661.7479652584254],      
              [0.0, 541.0606969363056, 317.4524205037745],
              [0.0,               0.0,               1.0]])

D = np.array([-0.042166406281296365, -0.001223961942208027, -0.0017036710622692108, 0.00023929900459453295])

# newSize = cv::Size(3400, 1940);
newSize = (850, 480)

# cv::Matx33d new_K;
new_K = np.eye(3)

# cv::fisheye::estimateNewCameraMatrixForUndistortRectify(K, D, cv::Size(W, H), cv::Mat::eye(3, 3, CV_64F), new_K, 1, newSize);    // W,H are the distorted image size
new_K = cv.fisheye.estimateNewCameraMatrixForUndistortRectify(K, D, (W, H), np.eye(3), new_K, 1, newSize)

# cv::fisheye::initUndistortRectifyMap(K, D, cv::Mat::eye(3, 3, CV_64F), new_K, newSize, CV_16SC2, mapx, mapy);
mapx, mapy = cv.fisheye.initUndistortRectifyMap(K, D, np.eye(3), new_K, newSize, cv.CV_16SC2);

# cv::remap(src, dst, mapx, mapy, cv::INTER_LINEAR);
dstY = cv.remap(srcY, mapx, mapy, cv.INTER_LINEAR)

# Resize mapx and mapy by a factor of x2 in each axis, and divide each element in the map by 2
shrank_mapSize = (mapx.shape[1]//2, mapx.shape[0]//2)
shrunk_mapx = cv.resize(mapx, shrank_mapSize, interpolation = cv.INTER_LINEAR) // 2
shrunk_mapy = cv.resize(mapy, shrank_mapSize, interpolation = cv.INTER_LINEAR) // 2

# Remap U and V using shunk maps
dstU = cv.remap(srcU, shrunk_mapx, shrunk_mapy, cv.INTER_LINEAR, borderValue=128)
dstV = cv.remap(srcV, shrunk_mapx, shrunk_mapy, cv.INTER_LINEAR, borderValue=128)

cv.imshow('dstY', dstY)
cv.imshow('dstU', dstU)
cv.imshow('dstV', dstV)

cv.waitKey(0)
cv.destroyAllWindows()

Result:

Y:
dstY

U:
dstU

V:
dstV

After converting to RGB:
RGB


C++ implementation considerations:

Since I420 format arranges Y, U and V as 3 continuous planes in memory, it's simple to set a pointer to each "plane", and treat it as a Grayscale image.
Same data ordering applies the output image - set 3 pointer to output "planes".

Illustration (assuming even width and height, and assume byte stride equals width):

srcY -> YYYYYYYY           dstY -> YYYYYYYYYYYY
        YYYYYYYY                   YYYYYYYYYYYY
        YYYYYYYY                   YYYYYYYYYYYY
        YYYYYYYY                   YYYYYYYYYYYY
        YYYYYYYY   remap           YYYYYYYYYYYY
        YYYYYYYY  ======>          YYYYYYYYYYYY
srcU -> UUUU                       YYYYYYYYYYYY
        UUUU               dstU -> YYYYYYYYYYYY
        UUUU                       UUUUUU
srcV -> VVVV                       UUUUUU
        VVVV                       UUUUUU
        VVVV                       UUUUUU
                           dstV -> VVVVVV
                                   VVVVVV
                                   VVVVVV
                                   VVVVVV

Implementing above illustration is C++

Under the assumption that width and height are even, and byte stride equals width, you can use the following C++ example for converting I420 to Y, U and V planes:

Assume: srcI420 is Wx(H*3/2) matrix in I420 format, like cv::Mat srcI420(cv::Size(W, H * 3 / 2), CV_8UC1);.

int W = 1280, H = 720;  //Assume resolution of Y plane is 1280x720

//Pointer to Y plane
unsigned char *pY = (unsigned char*)srcI420.data;

//Y plane as cv::Mat, resolution of srcY is 1280x720
cv::Mat srcY = cv::Mat(cv::Size(W, H), CV_8UC1, (void*)pY);

//U plane as cv::Mat, resolution of srcU is 640x360 (in memory buffer, U plane is placed after Y).
cv::Mat srcU = cv::Mat(cv::Size(W/2, H/2), CV_8UC1, (void*)(pY + W*H));

//V plane as cv::Mat, resolution of srcV is 640x360 (in memory buffer, V plane is placed after U).
cv::Mat srcV = cv::Mat(cv::Size(W / 2, H / 2), CV_8UC1, (void*)(pY + W*H + (W/2*H/2)));

//Display srcY, srcU, srcV for testing
cv::imshow("srcY", srcY);
cv::imshow("srcU", srcU);
cv::imshow("srcV", srcV);
cv::waitKey(0);

Above example uses pointer manipulations, without the need for copying the data.
You can use the same pointer manipulations for your destination I420 image.

Note: The solution is going to work in most cases, but not guaranteed to work in all cases.

4
  • Thanks for this wonderful answer. Regarding C++ implementation, it looks like 5 planes. 1 big and 4 small planes. Its easy to point header for the big one Mat(H, W, CV_8UC1, i420.data). How can a header be pointed for the small ones. Problem is they are horizontally concatenated.
    – Jai
    Jan 24 '20 at 8:51
  • Take my word on it... there are 3 planes: Y plane 1280x720, then U plane 640x360 then V plane 640x360. When displaying U and V as if their width were 1280, you are getting something that looks like 5 planes.
    – Rotem
    Jan 24 '20 at 9:13
  • I added a C++ code sample, for demonstrating how to implement the separation of I420 to Y, U, V planes.
    – Rotem
    Jan 24 '20 at 11:12
  • I understood what you tried to say about existence of 3 planes not 5 planes. The alternate rows of U plane are separated and transformed into two U images. Same goes with V plane. Thanks for your well crafted response.
    – Jai
    Jan 24 '20 at 11:31
0

EDIT: Components are not interleaved in the YV12 format, so the following will not work:

If the YV12 data is a one channel image, the interpolation of the remap operation is applied to the value represented by all three YUV data instead of individual Y, U and V components.

Therefore, roughly speaking, instead of doing a

c.YYYYYYYY, c.UU, c.VV

it will perform a

c.YYYYYYYYUUVV

during a linear interpolation.

You can perform a YV12 -> BGR color conversion after remap, but the colors of the interpolated pixels would be wrong.

Instead of doing a linear interpolation, try using a nearest-neighbor interpolation in remap. Then you should be able to get correct colors after YV12 -> BGR color conversion.

So, find mapx, mapy, then remap using INTER_NEAREST, and finally perform a YV12 -> BGR color conversion.

5
  • As far as I know in I420 data. First H number of rows are only Y data. and next H/2 number of rows are UV data.
    – Jai
    Jan 23 '20 at 11:51
  • @Jai In that case, the suggested approach will not work. I was not aware of this data arrangement.
    – dhanushka
    Jan 23 '20 at 12:00
  • Now I depicted the pixel arrangements in my post.
    – Jai
    Jan 23 '20 at 13:23
  • If you are not interested in chroma, you can undistort the luminance channel just by creating a matrix header with that data. Does your camera support packed pixel formats? YUV - VideoLAN Wiki
    – dhanushka
    Jan 23 '20 at 14:19
  • I understood. But I need the chroma also. I have to work with I420. Because later on, the I420 data will be fed to h264 video encoder,
    – Jai
    Jan 23 '20 at 15:18

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