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I'm currently working on a project that is supposed to represent data collected from gyroscope as a simple 3d graph, but what I wrote doesn't quite work - I simply integrated axes and then rotated the object.

Been looking for a solution and found something called rotation matrix, but I don't quite understand how it works - guess I need to take start angles [0,0,0] and convert them into such matrix, then take gyro data [yaw,pitch,roll] and convert them into similar matrix, multiply them and calculate new angles based on this new matrix? And repeat this every time I get new package of gyro data using previous matrix as 'base'?

Did I get it right? What I need is how to rotate object that's already rotated, are there any resources about on this subject somewhere? Been looking for '3d rotation matrix' but not quite what I've been looking for...

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A tutorial on rotation matrices, as well as the integration you need is described in the

Direction Cosine Matrix IMU: Theory

manuscript.

Long story short, you cannot "simply integrate the axes and then rotate the object", unfortunately it's more sophisticated than that. :( Don't worry though, the manuscript tells you step-by-step what to do.

Euler angles (aka roll, pitch and yaw) are evil, they screw up the stability of your app, see for example

They are not useful for interpolation either. Just use rotation matrices and you will be happy you did.

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Just for my understanding -- how do you think Euler angles differ from rotation matrices? How I learned it, Euler angle triplets can always be translated into a rotation matrix, and vice versa...I've been using quaternions to avoid the problems you mention; I know they are substantially different... –  Rody Oldenhuis Aug 15 '12 at 18:37
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"Euler angle triplets can always be translated into a rotation matrix, and vice versa" -- Well, most of the time, if you neglect the double cover and the singularity (gimbal lock) problems with Euler angles. You can also convert quaternions to rotation matrices and vice versa but you have double cover there too (AFAIK, never used). Euler angles, rotation matices and quaternions can all be used to represent the exact same thing, rotation, just be aware of the corner cases. –  Ali Aug 15 '12 at 18:59
    
+1 for refreshing my knowledge there –  Rody Oldenhuis Aug 15 '12 at 19:03
    
Correct me if Im wrong, but according to first link all I need to do is implement equation 17 (page 15), in which I multiply R(t) by matrix containing derivatives of gyro data? –  Benji Aug 15 '12 at 20:03
    
@Benji Yes, equation 17. No, no derivatives of the gyro data. The gyroscopes give you the omega, and you have to the sampling rate, dt. And that is all you need to compute R(t). –  Ali Aug 15 '12 at 20:52

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