## Hot answers tagged camera-calibration

38

Hmm, are you looking for "handsome" or "accurate"?
Camera calibration is one of the very few subjects in computer vision where accuracy can be directly quantified in physical terms, and verified by a physical experiment. And the usual lesson is that (a) your numbers are just as good as the effort (and money) you put into them, and (b) real accuracy (as ...

21

First to understand how you calculate it, it would help you if you read some things about the pinhole camera model and simple perspective projection. For a quick glimpse, check this. I'll try to update with more.
So, let's start by the opposite which describes how a camera works: project a 3d point in the world coordinate system to a 2d point in our image. ...

17

If you got extrinsic parameters then you got everything. That means that you can have Homography from the extrinsics (also called CameraPose). Pose is a 3x4 matrix, homography is a 3x3 matrix, H defined as
H = K*[r1, r2, t], //eqn 8.1, Hartley and Zisserman
with K being the camera intrinsic matrix, r1 and r2 being the first two ...

17

First off, your camera matrix is wrong. If you read the documentation, it should look like:
fx 0 cx
0 fy cy
0 0 1
If you look at yours, you've got it the wrong way round:
fx 0 0
0 fy 0
cx cy 1
So first, set camera_matrix to camera_matrix.T (or change how you construct camera_matrix. Remember that camera_matrix[i,j] is row i, column j).
...

13

I think you may be thinking of tvecs_new as the camera position. Slightly confusingly that is not the case! In fact its the position of the world origin in camera co-ords. To get the camera pose in the object/world co-ords, I believe you need to do:
`-np.matrix(rotation_matrix).T * np.matrix(tvecs_new)`
And you can get the Euler angles using ...

13

If you equate the world origin (0,0,0) with the camera focus (center of projection as you call it) and you assume the camera is pointing along the positive z-axis, then the situation looks like this in the plane x=0:
Here the axes are z (horizontal) and y (vertical). The subscript v is for "viewport" or screen, and w is for world.
If I get your ...

12

The simplest and most common way of doing undistort (also called unwarp or compensating for lens distortion) is to do a forward distortion on a chosen output photo size and then a reverse mapping using bilinear interpolation.
Here is code I wrote for performing this:
function I = undistort(Idistorted, params)
fx = params.fx;
fy = params.fy;
cx = params.cx;
...

11

In short: yes. In order to make a mathematical model that can describe a camera with rectangular pixels, you have to introduce two separate focal lengths. I'll quote from the often recommended "Learning OpenCV" (p. 373) which covers that section pretty well and which I recommend getting if you would like more background on this:
"The focal length fx (for ...

11

A few points.
Down-sizing, as you noticed, helps. That is because the corner-detection filters used in OpenCV to find the corners have fixed size, and that size of convolution mask may be too small to detect your corners - the image may actually look "smooth" at that scale, particularly where it is slightly blurry.
For the same reason, sharpening helps. ...

8

A lot of solutions to this question I think make hidden assumptions. I will try to give you a quick summary of how I think about this problem (I have had to think about it a lot in the past). Warping between two images is a 2 dimensional process accomplished by a 3x3 matrix called a homography. What you have is a 3x4 matrix which defines a transform in 3 ...

8

Sorry if this is too late - only just saw it.
The error is the reprojection of the fit. So find points on an image, calculate the real world model, recalculate where those points would be on the image given the model - report the difference. In a way this is a bit circular, you might have a model that is only correct for those few images which would then ...

8

I was confronted with the same problem as you, in OpenCV. I had a stereo image pair and I wanted to computed the external parameters of the cameras and the world coordinates of all observed points. This problem has been treated here:
Berthold K. P. Horn. Relative orientation revisited. Berthold K. P. Horn. Artificial Intelligence Laboratory, Massachusetts ...

7

First of all, you need to calibrate the intrinsic of the camera. Use checkerboard-patterns printed on cardboard to do this, OpenCV has methods for this although there are finished tools for this as well.
To get an idea, I have written some python code to calibrate from a live video stream, move the cardboard along the camera in some different angles and ...

7

Through trial and error, I realized that patternsize should be 7x7 since it is counting internal corners. This parameter has to be exact--8x8 won't work, but neither will anything less than 7x7.

7

The basic idea is that you have 2 cameras: one is the physical one (the one where you are retriving the images with opencv) and one is the opengl one. You have to align those two matrices.
To do that, you need to calibrate the physical camera.
First. You need a distortion parameters (because every lens more or less has some optical distortion), and build ...

7

This is a rather late answer, but for people coming to this from Google:
The correct way to check calibration accuracy is to use the reprojection error provided by OpenCV. I'm not sure why this wasn't mentioned anywhere in the answer or comments, you don't need to calculate this by hand - it's the return value of calibrateCamera. In Python it's the first ...

6

There are many possible sources of error.
First of all, while all three of the calibration implementations you have tried use essentially the same algorithm, there are enough differences that explain the discrepancies in the results.
The main difference is in the checkerboard corner detection. The Caltech Calibration Toolbox does not have automatic ...

6

The disparity map is basically the difference between the known and the observed pattern that you mention in the beginning. You use this during the depth computation.
The distance between the projector and the camera gets taken into account too.
Check out the following figure:
Pr is the position of a speckle in a reference depth Zr, and Po is the same ...

6

Couple of observations from my end.
1) Camera.autoFocus is a one-time call, applicable when
Camera.getParameters.getFocusMode() is either FOCUS-MODE-AUTO or
FOCUS-MODE-MACRO, in other cases you don't need to invoke the
autoFocus method. See the API Docs and follow them devotedly.
2) By one-time call, it means that this method does not register ...

6

So the IR pattern that the Kinect displays isn't your normal grid. For an example, check out this blog post. The Kinect handles making a normal depth map out of this. Thinking about focal lengths and such for this system is just going to dig yourself a hole. Your thoughts about precision are probably misplaced. The Kinect isn't accurate enough to BE picky ...

6

I don't have my H&Z to hand - but their old CVPR tutorial on the subject is here (for anyone else to have a look at w.r.t this question).
Just for clarity (and to use their terminology) the projection matrix P maps from Euclidean 3-space point (X) to an image point (x) as:
x = PX
where:
P = K[ R | t ]
defined by the (3x3) camera calibration matrix ...

6

In order to use vector[] you have to ensure that the vector has an element at that index. In this case, both the vectors are empty resulting in the access violation.
Change the declarations to:
vector<CvPoint2D32f> cornersR(n);
vector<CvPoint2D32f> cornersL(n);
which will populate the vectors with n default constructed instances of ...

6

Seems there's no good OpenCV way to do this.
I wound up using OCamLib to do the actual calibration, then writing my own "undistortPoints" function (using Scaramuzza's algorithms) to undistort 2D image points into 3D unit vectors (rather than 2D points). Unfortunately, this also breaks lots of other stuff in OpenCV because most OpenCV image processing ...

6

You can get an initial (rough) estimate of the focal length in pixel dividing the focal length in mm by the width of a pixel of the camera' sensor (CCD, CMOS, whatever).
You get the former from the camera manual, or read it from the EXIF header of an image taken at full resolution. Finding out the latter is a little more complicated: you may look up on the ...

6

General Meaning
A is unique up to Variation
A is the same as B up to Variation
A is equal to B up to Variation
Statement up to Variation
Phrases of the forms above typically mean that the Statement - the part before "up to" - is true excepting some kind of Variation. It can be thought of as meaning "...up to...but no further."
Example
...

6

The camera coordinates are the same as image coordinates. So You have x axe pointing in the right side from the camera, y axe is pointing down, and z is pointing in the direction caera is faced. This is a clockwise axe system, and the same would apply to the chessboard, so if You specified the origin in, lets say, upper right corner of the chessboard, x axe ...

5

### How to verify that the camera calibration is correct? (or how to estimate the error of reprojection)

The images used in generating the intrinsic calibration can also be used to verify it. A good example of this is the camera-calib tool from the Mobile Robot Programming Toolkit (MRPT).
Per Zhang's method, the MRPT calibration proceeds as follows:
Process the input images:
1a. Locate the calibration target (extract the chessboard corners)
1b. Estimate ...

5

Depends on the camera/lens and the accuracy you require, but you probably need more than 10 positions and you need to cover a wider range of view angles.
I'm assuming from the 800x600 that this is a webcam with a simple wide angle lens with lots of distortions. I would say you need 6-8 positions/rotations of the target in each of 3-4 different angles to the ...

5

My answer is "maybe" to the first question, and "no" to the second.
While it is true that it is not strictly necessary to calibrate with the target at the same or nearby distance as the subject, in practice it is possible only if you have enough depth of field (in particular, if you are focused at infinity), and use a fixed iris.
The reason is the Second ...

5

Given your configuration, errors of 20-40mm at the edges are average. It looks like you've done everything well.
Without modifying camera/system configuration, doing better will be hard. You can try to redo camera calibration and hope for better results, but this will not improve them alot (and you may eventually get worse results, so don't erase actual ...

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