Euler Angle Calculation from rotated reference frame

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Matthew
Matthew on 16 Jul 2012
Hello, I am trying to calculate Euler Angles from a rotated reference frame and am running into problems. I need to find the Euler angle rotations between the rotated reference frame and the original frame. I already have the reference frames calculated but I can't seem to correctly calculate the rotation. I first need to rotate about the x-axis, then y-axis and finally z-axis. I know that this is not the typical rotation order, but it is what the model I am simulating requires. I would greatly appreciate some help! Thanks!
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Matthew
Matthew on 16 Jul 2012
Yes I have the original and rotated frame already and want the Euler rotation angles and yes frame refers to xyz axes. I believe that there should be a unique answer as long as 2 angles are restricted to a range of [-pi,pi] and the other is restricted to [-pi/2,pi/2].
Jan
Jan on 16 Jul 2012
Edited: Jan on 16 Jul 2012
Please explain what "the reference frame" exactly means. Any explicit example would help us to formulate and answer as easy as possible.
While there is no "typical" rotation order, it matters if you want the transformation from the rotated to the reference system or the other way around.

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Answers (2)

James Tursa
James Tursa on 16 Jul 2012
You can use this FEX submission by John Fuller to convert from a direction cosine matrix to any Euler Angle sequence you like:
http://www.mathworks.com/matlabcentral/fileexchange/20696-function-to-convert-between-dcm-euler-angles-quaternions-and-euler-vectors
Jan
Jan on 16 Jul 2012
XYZ means, that you are looking for an Euler-Cardan angle, not an Euler angle.
Here "BC" is the child system, while "BP" is the parent. The fields X, Y, Z are [n x 3] matrices, which contain the 1x3 ortho-normal local coordinate vectors.
% case 'xyz' % EULER-CARDAN
% c=cos, s=sin, i means the i.th component
% X = [c3.*c2, c3.*s2.*s1+s3.*c1, -c3.*s2.*c1+s3.*s1];
% Y = [-s3.*c2, -s3.*s2.*s1+c3.*c1, s3.*s2.*c1+c3.*s1];
% Z = [s2, -c2.*s1, c2.*c1];
% REAL(ASIN(X)) catchs rounding errors:
% if X is greater than 1.0, ASIN(X) is complex.
EM = [atan2(Dot(BC.Y, BP.Z), Dot(BC.Z, BP.Z)), ...
real(asin(-Dot(BC.X, BP.Z))), ...
atan2(Dot(BC.X, BP.Y), Dot(BC.X, BP.X))]
function R = Dot(X, Y);
R = X(:, 1) .* Y(:, 1) + X(:, 2) .* Y(:, 2) + X(:, 3) .* Y(:, 3);

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