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!