I have a height map for an image, which tells me the offset of each pixel in the Z direction. My goal is to flatten a distorted image using only it's height map.
How would I go about doing this? I know the position of the camera, if that helps.
To do this, I was thinking about assuming that each pixel was a point on a plane, and then to translate each of those points vertically according to the Z-value I get from the height map, and from that translation (imagine you are looking at the points from above; the shift will cause the point to move around from your perspective).
From that projected shift, I could extract X and Y-shift of each pixel, which I could feed into
But I have no idea how I could get the projected 3D offset of a point with OpenCV, let alone construct a offset map out of it.
Here are my reference images for what I'm doing:
I know the angle of the lasers (45 degrees), and from the calibration images, I can calculate the height of the book really easily:
h(x) = sin(theta) * abs(calibration(x) - actual(x))
I do this for both lines and linearly interpolate the two lines to generate a surface using this approach (Python code. It's inside a loop):
height_grid[x][y] = heights_top[x] * (cv.GetSize(image) - y) + heights_bottom[x] * y
I hope this helps ;)
Right now, this is what I have to dewarp the image. All that strange stuff in the middle projects a 3D coordinate onto the camera plane, given it's position (and the camera's location, rotation, etc.):
class Point: def __init__(self, x = 0, y = 0, z = 0): self.x = x self.y = y self.z = z mapX = cv.CreateMat(cv.GetSize(image), cv.GetSize(image), cv.CV_32FC1) mapY = cv.CreateMat(cv.GetSize(image), cv.GetSize(image), cv.CV_32FC1) c = Point(CAMERA_POSITION, CAMERA_POSITION, CAMERA_POSITION) theta = Point(CAMERA_ROTATION, CAMERA_ROTATION, CAMERA_ROTATION) d = Point() e = Point(0, 0, CAMERA_POSITION + SENSOR_OFFSET) costx = cos(theta.x) costy = cos(theta.y) costz = cos(theta.z) sintx = sin(theta.x) sinty = sin(theta.y) sintz = sin(theta.z) for x in xrange(cv.GetSize(image)): for y in xrange(cv.GetSize(image)): a = Point(x, y, heights_top[x / 2] * (cv.GetSize(image) - y) + heights_bottom[x / 2] * y) b = Point() d.x = costy * (sintz * (a.y - c.y) + costz * (a.x - c.x)) - sinty * (a.z - c.z) d.y = sintx * (costy * (a.z - c.z) + sinty * (sintz * (a.y - c.y) + costz * (a.x - c.x))) + costx * (costz * (a.y - c.y) - sintz * (a.x - c.x)) d.z = costx * (costy * (a.z - c.z) + sinty * (sintz * (a.y - c.y) + costz * (a.x - c.x))) - sintx * (costz * (a.y - c.y) - sintz * (a.x - c.x)) mapX[y, x] = x + (d.x - e.x) * (e.z / d.z) mapY[y, x] = y + (d.y - e.y) * (e.z / d.z) print print 'Remapping original image using map...' remapped = cv.CreateImage(cv.GetSize(image), 8, 3) cv.Remap(image, remapped, mapX, mapY, cv.CV_INTER_LINEAR)
This is turning into a huge thread of images and code now... Anyways, this code chunk takes my 7 minutes to run on a 18MP camera image; that's way too long, and in the end, this approach does nothing to the image (the offset for each pixel is