# How to calculate extrinsic parameters of one camera relative to the second camera?

I have calibrated 2 cameras with respect to some world coordinate system. I know rotation matrix and translation vector for each of them relative to the world frame. From these matrices how to calculate rotation matrix and translation vector of one camera with respect to the other??

Any help or suggestion please. Thanks!

-

First convert your rotation matrix into a rotation vector. Now you have 2 3d vectors for each camera, call them A1,A2,B1,B2. You have all 4 of them with respect to some origin O. The rule you need is

``````A relative to B = (A relative to O)- (B relative to O)
``````

Apply that rule to your 2 vectors and you will have their pose relative to one another.

Some documentation on converting from rotation matrix to euler angles can be found here as well as many other places. If you are using openCV you can just use Rodrigues. Here is some matlab/octave code I found.

-
Thanks a lot for your answer! Could you please explain a little bit how to convert rotation matrix into 2 3D vectors? I guess you mean axis-angle representation of the rotation matrix. I have 3x3 rotation matrix R1, and 3D translation vector T1 for the first camera and R2, T2 for the second camera. –  Karmar Sep 5 '12 at 17:53
You convert the rotation matrix into 1 3d vector and the translation vector is the other 3d vector and yes I mean the axis-angle representation. –  Hammer Sep 5 '12 at 19:00
Thanks. One more question, please. Could you give some link or source code on C for rotation matrix->axis-angle conversion? –  Karmar Sep 5 '12 at 20:09
see updated answer –  Hammer Sep 5 '12 at 20:28
Yes, I am using OpenCV, the function is exactly what I need. Thanks a lot, your answers really help me! –  Karmar Sep 5 '12 at 20:35

Here is an easier solution, since you already have the 3x3 rotation matrices R1 and R2, and the 3x1 translation vectors t1 and t2.

These express the motion from the world coordinate frame to each camera, i.e. are the matrices such that, if p is a point expressed in world coordinate frame, then the same point expressed in, say, camera 1 frame is p1 = R1 * p + t1.

The motion from camera 1 to 2 is then simply the composition of (a) the motion FROM camera 1 TO the world frame, and (b) of the motion FROM the world frame TO camera 2. You can easily compute this composition as follows:

1. Form the 4x4 roto-translation matrices Qw1 = [R1 t1] and Qw2 = [ R2 t2 ], both with the 4th row equal to [0 0 0 1]. These matrices completely express the roto-translation FROM the world coordinate frame TO camera 1 and 2 respectively.
2. The motion FROM camera 1 TO the world frame is simply Q1w = inv(Qw1). Here inv() is the algebraic inverse matrix, i.e. the one such that inv(X) * X = X * inv(X) = IdentityMatrix, for every nonsingular matrix X.
3. The roto-translation from camera 1 to 2 is then Q12 = Q1w * Qw2, and viceversa, the one from camera 2 to 1 is Q21 = Q2w * Qw1 = inv(Qw2) * Qw1.

Once you have Q12 you can extract from it the rotation and translation parts, if you so wish, respectively from its upper 3x3 submatrix and right 3x1 sub-column.

-
Thank you for your feedback and detailed explanation! –  Karmar Sep 6 '12 at 12:21