I am using two image of the single object the object is roated certain degree from its first image.

I have calculated the POSE of each image and converted the rotational vector to Matrix using Rodergues(). Now how do I calculate and see how much it is rotated from its first position?

I have tried many ways but answers was no were close

EDIT: My camera is fixed only the object is moving.


We can get Euler angles from rotation matrix using following formula.

Given a 3×3 rotation matrix

enter image description here

The 3 Euler angles are

enter image description here

enter image description here

enter image description here

Here atan2 is the same arc tangent function, with quadrant checking, you typically find in C or Matlab.

Note: Care must be taken if the angle around the y-axis is exactly +/-90°. In that case all elements in the first column and last row, except the one in the lower corner, which is either 1 or -1, will be 0 (cos(1)=0). One solution would be to fix the rotation around the x-axis at 180° and compute the angle around the z-axis from: atan2(r_12, -r_22).

See also https://www.geometrictools.com/Documentation/EulerAngles.pdf, which includes implementations for six different orders of Euler angles.

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  • 1
    Thank you so much for your help.. +1 – N.J Feb 26 '13 at 10:03
  • Is there also a way to determine in which order these rotations have to be applied to achieve this matrix? – x squared Sep 13 '14 at 11:20
  • Here, the order of rotation is Rx, then Ry, then Rz. Thus RzRyRx=R – Patrick Stalph May 25 '18 at 7:37
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    How was the cosine part of the pitch calculation obtained (sqrt of r_32^2 + r_33^3)? Most literature I read only gives an arc sine calculation for the pitch. On a ZYX matrix I can also get the same via sqrt of r_00^2+r_10^2. – John Ernest Dec 7 '19 at 6:02

If R is the (3x3) rotation matrix, then the angle of rotation will be acos((tr(R)-1)/2), where tr(R) is the trace of the matrix (i.e. the sum of the diagonal elements).

That is what you asked for; I estimate a 90% chance that it is not what you want.

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  • this gives exactly one scalar value corresponding to the angle of rotation along which axis? – Saravanabalagi Ramachandran Dec 6 '17 at 22:37
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    @SaravanabalagiRamachandran: The eigenvector of the matrix, of course. Just solve (R-I)X= 0 for X (where X and 0 are vectors). – Beta Dec 7 '17 at 1:19
  • What is angle of rotation in this case? – mrgloom Oct 14 '19 at 16:51

For your reference, this code computes the Euler angles in MATLAB:

function Eul = RotMat2Euler(R)

if R(1,3) == 1 | R(1,3) == -1
  %special case
  E3 = 0; %set arbitrarily
  dlta = atan2(R(1,2),R(1,3));
  if R(1,3) == -1
    E2 = pi/2;
    E1 = E3 + dlta;
    E2 = -pi/2;
    E1 = -E3 + dlta;
  E2 = - asin(R(1,3));
  E1 = atan2(R(2,3)/cos(E2), R(3,3)/cos(E2));
  E3 = atan2(R(1,2)/cos(E2), R(1,1)/cos(E2));

Eul = [E1 E2 E3];

Code provided by Graham Taylor, Geoff Hinton and Sam Roweis. For more information, see here

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  • I wanted to try it, so I wrote a Python version: import numpy as np def rot_mat_to_euler(r): if (r[0, 2] == 1) | (r[0, 2] == -1): # special case e3 = 0 # set arbitrarily dlt = np.arctan2(r[0, 1], r[0, 2]) if r[0, 2] == -1: e2 = np.pi/2 e1 = e3 + dlt else: e2 = -np.pi/2 e1 = -e3 + dlt else: e2 = -np.arcsin(r[0, 2]) e1 = np.arctan2(r[1, 2]/np.cos(e2), r[2, 2]/np.cos(e2)) e3 = np.arctan2(r[0, 1]/np.cos(e2), r[0, 0]/np.cos(e2)) return [e1, e2, e3] – Бојан Матовски Apr 5 '19 at 16:39

Let R1c and R2c be the 2 rotation matrices you have computed. These express the rotations from the object in poses 1 and 2 respectively to the camera frame (hence the second c suffix). The rotation matrix you want is from pose 1 to pose 2, i.e. R12. To compute it you must rotate, in your mind, the object from pose_1-to-camera, then from the camera-to-pose_2. The latter rotation is the inverse of the pose_2-to-camera espressed by R2c, hence:

R12 = R1c * inv(R2c)

From matrix R12 you can then compute the angle and axis of rotation using Rodiguez's formula.

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Would like to put a contribution here as I was working on the same problem. I add value to the above answers by posting a pure python implementation for converting a 3-D rotation matrix (3x3) to the corresponding roll (Rx) , pitch (Ry) , yaw (Rz) angles.

Reference pseudocode: https://www.gregslabaugh.net/publications/euler.pdf

Reference problem setup: Say we have a 3x3 rotation matrix and we want to extract the Euler angles in degrees. I will make the Python implementation as 'obvious' as possible to make it easy to decipher what is going on in the script. Respective programmers can optimize it for their own use.

Assumptions: We rotate the first about the x-axis, followed by the y-axis, and finally the z-axis. This ordering-definition must be respected when you are adapting this code snippet.

Illustration of the rotation matrix / sometimes called 'orientation' matrix
R = [ 
       R11 , R12 , R13, 
       R21 , R22 , R23,
       R31 , R32 , R33  

1. this implementation is meant to make the mathematics easy to be deciphered
from the script, not so much on 'optimized' code. 
You can then optimize it to your own style. 

2. I have utilized naval rigid body terminology here whereby; 
2.1 roll -> rotation about x-axis 
2.2 pitch -> rotation about the y-axis 
2.3 yaw -> rotation about the z-axis (this is pointing 'upwards') 
from math import (
    asin, pi, atan2, cos 

if R31 != 1 and R31 != -1: 
     pitch_1 = -1*asin(R31)
     pitch_2 = pi - pitch_1 
     roll_1 = atan2( R32 / cos(pitch_1) , R33 /cos(pitch_1) ) 
     roll_2 = atan2( R32 / cos(pitch_2) , R33 /cos(pitch_2) ) 
     yaw_1 = atan2( R21 / cos(pitch_1) , R11 / cos(pitch_1) )
     yaw_2 = atan2( R21 / cos(pitch_2) , R11 / cos(pitch_2) ) 

     # IMPORTANT NOTE here, there is more than one solution but we choose the first for this case for simplicity !
     # You can insert your own domain logic here on how to handle both solutions appropriately (see the reference publication link for more info). 
     pitch = pitch_1 
     roll = roll_1
     yaw = yaw_1 
     yaw = 0 # anything (we default this to zero)
     if R31 == -1: 
        pitch = pi/2 
        roll = yaw + atan2(R12,R13) 
        pitch = -pi/2 
        roll = -1*yaw + atan2(-1*R12,-1*R13) 

# convert from radians to degrees
roll = roll*180/pi 
pitch = pitch*180/pi
yaw = yaw*180/pi 

rxyz_deg = [roll , pitch , yaw] 

Hope this helps fellow coders out there!

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