# Remap rotation matrix to different axis system

I am using an adapted version of android's getRotationMatrix in a c++ program that reads the phone's sensor data over the network and calculates the device's matrix.

The function works fine and calculates the device's orientation. Unfortunately, Ogre3d has a different axis system than the device. So even though rotation about the x-axis works fine, the y and z axis are wrong. Holding the device level and pointing to north (identity matrix). When I pitch, the rotation is correct. But when I roll and yaw the rotations are alternated. Roll is yaw in Ogre3d and vice versa.

``````    (Ogre3d)                         ([Device][5])

^ +y-axis                       ^ +z-axis
*                               *
*                               *
*                               *    ^ +y-axis
*                               *   *
*                               *  *
*                               * *
************> + x-axis          ************> +x-axis
*
*
v +z-axis
``````

A quick look at the two axis system looks like Ogre's system (on the left) is essentially the device's system rotated 90 degrees counter clockwise about the x-axis.

I tried to experiment with various combinations when I fist assign sensor values before the matrix is calculated but no combination seems to work correctly. How would I make sure that the rotation matrix getRotationMatrix() produces displays correctly on Ogre3D?

For Reference here is the function that calculates the matrix:

``````bool getRotationMatrix() {
//sensor data coming through the network are
//stored in accel(accelerometer) and mag(geomagnetic)
float Ax = accel[0]; float Ay = accel[1];   float Az = accel[2];
float Ex = mag[0];   float Ey = mag[1];     float Ez = mag[2];

float Hx = Ey * Az - Ez * Ay;
float Hy = Ez * Ax - Ex * Az;
float Hz = Ex * Ay - Ey * Ax;
float normH = (float) Math::Sqrt(Hx * Hx + Hy * Hy + Hz * Hz);
if (normH < 0.1f) {
// device is close to free fall (or in space?), or close to
// magnetic north pole. Typical values are  > 100.
return false;
}
float invH = 1.0f / normH;
Hx *= invH;
Hy *= invH;
Hz *= invH;
float invA = 1.0f / (float) Math::Sqrt(Ax * Ax + Ay * Ay + Az * Az);
Ax *= invA;
Ay *= invA;
Az *= invA;
float Mx = Ay * Hz - Az * Hy;
float My = Az * Hx - Ax * Hz;
float Mz = Ax * Hy - Ay * Hx;

//ogre3d's matrix3 is column-major whereas getrotatinomatrix produces
//a row-major matrix thus i have tranposed it here
orientation[0][0] = Hx; orientation[0][2] = Mx; orientation[0][2] = Ax;
orientation[1][0] = Hy; orientation[1][3] = My; orientation[1][2] = Ay;
orientation[2][0] = Hz; orientation[2][4] = Mz; orientation[2][2] = Az;

return true;
}
``````
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Just wondering, is it legal to use code ported code from Android like that? I wish I understood the meaning behind the math (which I presume is not IP) so that I could write it on my own. –  Plumenator May 31 '11 at 6:36
Of course it's legal. acc = data from accelerometer ma = data from magnetic sensor. Here's the Ogre3D functions, it think it's pretty straightforward: Vector3 H = ma.crossProduct(acc); float normH = (float) H.length(); float invH = 1.0f / normH; H *= invH; float invA = 1.0f / (float) acc.length(); acc *= invA; Vector3 M = acc.crossProduct(H); orientation[0][0] = H.x; orientation[0][1] = H.y; orientation[0][2] = H.z; orientation[1][0] = M.x; orientation[1][1] = M.y; orientation[1][2] = M.z; orientation[2][0] = acc.x; orientation[2][1] = acc.y; orientation[2][2] = acc.z; –  Jubei Jun 8 '11 at 11:14
True, but we just took the Java code from Android and converted to C++. Is that legal? Shouldn't we have written the code from scratch or have come up with it entirely by ourselves? –  Plumenator Jun 8 '11 at 12:03
But the method is a very well known method of determining orientation based on two known vectors from 1968. Google does not own any patents or rights on that method. en.wikipedia.org/wiki/Triad_Method –  Jubei Jun 10 '11 at 4:32
The problem isn't the method. It's the fact that the code is derived from the one Google owns. –  Plumenator Jun 10 '11 at 7:05

Why not just add the one additional rotation you've already identified before you use it in ogre?

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I don't know much about Matrix Rotation, but if the Systems rotates like you are showing, I think that youshould do the following:

X Axis stays the same way, so:

``````float Ax = accel[0];
float Ex = mag[0];
``````

Y Axis in (Ogre3d) is Z axis in ([Device][5]), so:

``````float Ay = accel[2];
float Ey = mag[2];
``````

Z Axis in (Ogre3d) is the oposite of Y axis in ([Device][5]), so:

``````float Az = accel[1] * (-1);
float Ez = mag[1] * (-1);
``````

Try that

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I have already tried that. I tried it again and unfortunately it doesn't work :/ It does switch y with z but the rotation on the z axis is reversed and no matter what combination I try I can't get it right (been trying for several days now). Thank you though! I appreciate the help. –  Jubei May 1 '11 at 12:52

I found the problem. In my function the unit vectors calculated after the cross products I put them in columns whereas I should be putting them in the rows in their appointed matrix3 cells as usual. Something about row-major and column-major confused me even though I was referring to the elements in 2d [][].

multiplying the outcome of the matrix calculation function with this matrix:

1 0 0

0 0 1

0 -1 0

Then pitching the whole result by another p/2 about axis solved the remap problem but I fear my geometry is inverted.

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