# Euler angles from a 2x2 ZYZ rotation matrix?

How I can find the euler angles from a random 2x2 ZYZ rotation matrix? We know that all SU(2) matrices can be decomposed, using the ZYZ decomposition, as a three matrices product based in euler angles. In the Wikipedia about euler angles:

"A similar three angle decomposition applies to SU(2), the special unitary group of rotations in complex 2D space, with the difference that β ranges from 0 to 2π. These are also called Euler angles."

I have did try do a equations system in the matlab, but it found the solution in some cases (pauli matrices) and in many other not. It never find to a random SU(2) matrix.

Anybody know a general approach? I already did found how to do 3x3 matrices, but not for 2x2 ZYZ.

Best regards!

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Am I missing something? There is only one possible rotation for 2x2 matices. Only rotation about Z can be represented. Can you give an example so we can understand. –  ja72 Jan 30 '13 at 19:04
Of course. All SU(2) matrix can be, ignoring a global phase factor, decomposed as: U = e^{-i/2 * t1 * Z} * e^{-i/2 * t2 * Y} * e^{-i/2 * t3 * Z}, where Y and Z are Pauli matrices, Y = [0 -i; i 0] e Z = [1 0; 0 -1]. This is the ZYZ rotation. –  user901366 Jan 31 '13 at 15:02
Yeah, you might want to put all this in the original question, and include references as it is critical to an answer. –  ja72 Jan 31 '13 at 19:45
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## 1 Answer

from https://groups.google.com/forum/?fromgroups=#!topic/mathtools/q25a5WoG6Eo, written by Haifeng GONG (didn't you find it by yourself):

``````function orthm = ang2orth(ang)

sa = sin(ang(2)); ca = cos(ang(2));
sb = sin(ang(1)); cb = cos(ang(1));
sc = sin(ang(3)); cc = cos(ang(3));

ra = [  ca,  sa,  0; ...
-sa,  ca,  0; ...
0,   0,  1];
rb = [  cb,  0,  sb; ...
0,  1,  0; ...
-sb,  0,  cb];
rc = [  1,   0,   0; ...
0,   cc, sc;...
0,  -sc, cc];
orthm = rc*rb*ra;

function ang = orth2ang(orthm)
ang(1) = asin(orthm(1,3)); %Wei du
ang(2) = angle( orthm(1,1:2)*[1 ;i] ); %Jing Du
yz = orthm* ...
[orthm(1,:)',...
[-sin(ang(2)); cos(ang(2)); 0],...
[-sin(ang(1))*cos(ang(2)); -sin(ang(1)*sin(ang(2)));
cos(ang(1))] ];

ang(3) = angle(yz(2,2:3)* [1; i]); % Xuan Du
``````

As can be seen here and here `There is an isomorphism between SO(3) and SU(2)`:

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Hi friend, thanks, but this algorithm is for 3d rotation. I need for 2x2 complex matrices. –  user901366 Jan 31 '13 at 14:56
The transition between 2d to 3d is to set one of the axis has a const plane let say z=0, do it carefully –  0x90 Jan 31 '13 at 18:44
Excuse-me, I not understand. Could I convert the complex 2x2 matrix U = [0.2762 + 0.2832i 0.6413 + 0.6575i; -0.6413 + 0.6575i 0.2762 - 0.2832i] to a 3x3 real matrix and apply the above approach? –  user901366 Feb 1 '13 at 13:55
you can do it in a lot of ways, you can insist that the rotation according to z will be 2pi or zero let's say. doesn't make sense for you? –  0x90 Feb 1 '13 at 14:03
Of course. I use the map defined in the page 4 of this reference to transform a 2x2 complex matrix in a 3x3 real rotation matrix. Then I use this matlab implementation to extract euler angles. But it does not work for all the cases.. :( If I try with Pauli matrices I don't get know values. :( –  user901366 Feb 3 '13 at 16:35
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