This is a problem concerning stereo calibration and rectification using openCV (vers. 4.5.1.48) and Python (vers. 3.8.5).
I have two cameras placed on the same axis as shown on the image below:
The left (upper) camera is taking pictures with 640x480 resolution, while the right (lower) camera is taking pictures with 320x240 resolution. The goal is to find an object on the right image (320x240) and crop out the same object on the left image (640x480). In other words; To transfer the rectangle that makes up the object in the right image, to the left image. This idea is sketched below.
A red object is found on the right image and I need to transfer it's location to left image and crop it out. The objects is placed on a flat plane 30cm from the camera lenses. In other words; The distance (depth) from the two cameras lenses to the flat plane is constant (30cm).
This main question is about how transfer a location from one image to another, when two cameras are placed side by side, when the images are of different resolutions and when the depth is (fairly) constant. It's not a question about finding objects.
To solve this problem, as far as I know, stereo calibration must be used, and I have found the following articles/code, among other things:
- https://github.com/bvnayak/stereo_calibration/blob/master/camera_calibrate.py
- https://opencv-python-tutroals.readthedocs.io/en/latest/py_tutorials/py_calib3d/py_calibration/py_calibration.html
- https://python.plainenglish.io/the-depth-i-stereo-calibration-and-rectification-24da7b0fb1e0
Below are an example of a calibration pattern that I used:
I have 25 photos of the calibration pattern with the left and right camera. The pattern is 5x9 and the square sizes is 40x40 mm.
Based on my knowledge, I have written the following code:
import numpy as np
import cv2
import glob
CALIL = "path-to-left-images"
CALIR = "path-to-right-images"
# Termination criterias
criteria1 = (cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, 30, 0.001)
criteria2 = (cv2.TERM_CRITERIA_EPS + cv2.TERM_CRITERIA_MAX_ITER, 100, 1e-5)
# Chessboard parameters
checker_size = 40.0 # Square size in world units (mm)
checker_pattern = (5, 9) # 5 rows, 9 columns
# Flags
findChessboardCorners_flags = 0
#findChessboardCorners_flags |= cv2.CALIB_CB_ADAPTIVE_THRESH
#findChessboardCorners_flags |= cv2.CALIB_CB_NORMALIZE_IMAGE
#findChessboardCorners_flags |= cv2.CALIB_CB_FILTER_QUADS
#findChessboardCorners_flags |= cv2.CALIB_CB_FAST_CHECK
calibrateCamera_flags = 0
#calibrateCamera_flags |= cv2.CALIB_USE_INTRINSIC_GUESS
#calibrateCamera_flags |= cv2.CALIB_FIX_PRINCIPAL_POINT
#calibrateCamera_flags |= cv2.CALIB_FIX_ASPECT_RATIO
#calibrateCamera_flags |= cv2.CALIB_ZERO_TANGENT_DIST
#calibrateCamera_flags |= cv2.CALIB_FIX_K1 # K2, K3...K6
#calibrateCamera_flags |= cv2.CALIB_RATIONAL_MODEL
#calibrateCamera_flags |= cv2.CALIB_THIN_PRISM_MODEL
#calibrateCamera_flags |= cv2.CALIB_FIX_S1_S2_S3_S4
#calibrateCamera_flags |= cv2.CALIB_TILTED_MODEL
#calibrateCamera_flags |= cv2.CALIB_FIX_TAUX_TAUY
stereoCalibrate_falgs = 0
stereoCalibrate_falgs |= cv2.CALIB_FIX_INTRINSIC
#stereoCalibrate_falgs |= cv2.CALIB_USE_INTRINSIC_GUESS
#stereoCalibrate_falgs |= cv2.CALIB_USE_EXTRINSIC_GUESS
#stereoCalibrate_falgs |= cv2.CALIB_FIX_PRINCIPAL_POINT
#stereoCalibrate_falgs |= cv2.CALIB_FIX_FOCAL_LENGTH
#stereoCalibrate_falgs |= cv2.CALIB_FIX_ASPECT_RATIO
#stereoCalibrate_falgs |= cv2.CALIB_SAME_FOCAL_LENGTH
#stereoCalibrate_falgs |= cv2.CALIB_ZERO_TANGENT_DIST
#stereoCalibrate_falgs |= cv2.CALIB_FIX_K1 # K2, K3...K6
#stereoCalibrate_falgs |= cv2.CALIB_RATIONAL_MODEL
#stereoCalibrate_falgs |= cv2.CALIB_THIN_PRISM_MODEL
#stereoCalibrate_falgs |= cv2.CALIB_FIX_S1_S2_S3_S4
#stereoCalibrate_falgs |= cv2.CALIB_TILTED_MODEL
#stereoCalibrate_falgs |= cv2.CALIB_FIX_TAUX_TAUY
stereoRectify_flags = 0
stereoRectify_flags |= cv2.CALIB_ZERO_DISPARITY
# Prepare object points, like (0,0,0), (1,0,0), (2,0,0) ....,(6,5,0)
objp = np.zeros((1, checker_pattern[0] * checker_pattern[1], 3), np.float32)
objp[0, :, :2] = np.mgrid[0:checker_pattern[0],
0:checker_pattern[1]].T.reshape(-1, 2)*checker_size
# Arrays to store object points and image points from all the images.
objPoints = [] # 3d point in real world space
imgPointsL = [] # 2d points in image plane, left image (normal)
imgPointsR = [] # 2d points in image plane, right image (thermal)
# Get calibration images
# Get all left (normal) images from directory. Sort them
images_left = glob.glob(CALIL+'*')
images_left.sort()
# Get all right (thermal) images from directory. Sort them
images_right = glob.glob(CALIR+'*')
images_right.sort()
for left_img, right_img in zip(images_left, images_right):
# Left object points
imgL = cv2.imread(left_img)
grayL = cv2.cvtColor(imgL, cv2.COLOR_BGR2GRAY)
# Find the chessboard corners
retL, cornersL = cv2.findChessboardCorners(
grayL, (checker_pattern[0], checker_pattern[1]), findChessboardCorners_flags)
# Right object points
imgR = cv2.imread(right_img)
grayR = cv2.cvtColor(imgR, cv2.COLOR_BGR2GRAY)
# Find the chessboard corners
retR, cornersR = cv2.findChessboardCorners(
grayR, (checker_pattern[0], checker_pattern[1]), findChessboardCorners_flags)
if retL and retR:
# If found, add object points, image points (after refining them)
objPoints.append(objp)
# Left points
cornersL2 = cv2.cornerSubPix(
grayL, cornersL, (5, 5), (-1, -1), criteria1)
imgPointsL.append(cornersL2)
# Right points
cornersR2 = cv2.cornerSubPix(
grayR, cornersR, (5, 5), (-1, -1), criteria1)
imgPointsR.append(cornersR2)
shapeL = grayL.shape[::-1]
shapeR = grayR.shape[::-1]
# Calibrate each camera separately
retL, K1, D1, R1, T1 = cv2.calibrateCamera(
objPoints, imgPointsL, shapeL, None, None, flags=calibrateCamera_flags)
retR, K2, D2, R2, T2 = cv2.calibrateCamera(
objPoints, imgPointsR, shapeR, None, None, flags=calibrateCamera_flags)
# Stereo calibrate
ret, K1, D1, K2, D2, R, T, E, F = cv2.stereoCalibrate(
objPoints, imgPointsL, imgPointsR, K1, D1, K2, D2, shapeR, flags=calibrateCamera_flags, criteria=criteria2)
# Stereo rectify
R1, R2, P1, P2, Q, roi_left, roi_right = cv2.stereoRectify(
K1, D1, K2, D2, shapeR, R, T, flags=stereoRectify_flags, alpha=1)
# Undistort images
leftMapX, leftMapY = cv2.initUndistortRectifyMap(
K1, D1, R1, P1, shapeL, cv2.CV_32FC1)
rightMapX, rightMapY = cv2.initUndistortRectifyMap(
K2, D2, R2, P2, shapeR, cv2.CV_32FC1)
# Remap
left_rectified = cv2.remap(images_left[0], leftMapX, leftMapY,
cv2.INTER_LINEAR, cv2.BORDER_CONSTANT)
right_rectified = cv2.remap(images_right[0], rightMapX, rightMapY,
cv2.INTER_LINEAR, cv2.BORDER_CONSTANT)
But I get a bad result:
I have tried different flags, alpha-parameters, but nothing works...
Questions:
- Is it even possible to stereo calibrate and solve this problem, when the two images are of different resolutions?
- Is the general workflow correct or am I missing something? Flags? Alpha-parameter? Other ways to solve this problem?
EDIT
After the great comments from Micha I've found out that perspective homography is (hopefully) the way to solve this problem, and not stereo calibration. This is because the objects, that need to be found, is placed on a flat surface at a constant length/depth from the two camera lenses (30cm).
Based on the new information, I've written the following code, where I've used the first pair of images to get the perspective transformation matrix:
imgL = cv2.imread(images_left[0])
imgL = cv2.cvtColor(imgL, cv2.COLOR_BGR2GRAY)
imgR = cv2.imread(images_right[0])
imgR = cv2.cvtColor(imgR, cv2.COLOR_BGR2GRAY)
ret1, corners1 = cv2.findChessboardCorners(imgL, (checker_pattern[0], checker_pattern[1]))
cornersL2 = cv2.cornerSubPix(imgL, corners1, (5, 5), (-1, -1), criteria1)
ret2, corners2 = cv2.findChessboardCorners(imgR, (checker_pattern[0], checker_pattern[1]))
cornersR2 = cv2.cornerSubPix(imgR, corners2, (5, 5), (-1, -1), criteria1)
H, _ = cv2.findHomography(cornersL2, cornersR2)
Based on the perspective transformation matrix, H, I can use the cv2.warpPerspective()
function to warp the left image based on the right image and the chessboard corners in the calibration plate.
However, when I try to warp it, the warped image (upper image below) is a bit to the right relative to the other (lower) image, as seen on the image below:
The result of the crop out is shown below, where the areas doesn't match:
I think I need to resize the warped image so it's the same resolution as the right image (320x240). The warped image has the resolution 640x240.
Questions:
- Should the calibration plate be placed 30cm from the camera lenses for an optimal calculation of the perspective transformation matrix?
- I have 25 images of the calibration plate from different angels. Is it necessary to use all images, or just one?
- I'm using the
cv2.warpPerspective()
function, but the crop out doesn't match up. Should i use other functions?
img = img[y:y+h, x:x+w]
, where x, y, w and h have been found according to an object on the right image and then scaled correctly to the left image.