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I have gyroscope + accelerometer data at each time period T.

Using C++, I want to calculate the rotation of the object at each time - it can rotate on its axes. I've read that it is convenient to represent the rotation of the system in terms of quaternions (not in Euler angles).

How can I transform from angular velocity (from gyroscope) to the quaternions representation? I think in order to do it I need to solve the differential equation using numerical methods.

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4 Answers 4

up vote 6 down vote accepted

I'm not sure which language you're looking for, but the C++ Boost library has a working Quaternion class (quaternion.hpp). I've used this library to create a simple rotation class for computing the results or rotating points about arbitrary vectors with very little difficulty.

UPDATE: Based on your comment, I don't think you necessarily need to use a quaternion library to figure out your angular position at a given time, given either a constant angular velocity or angular acceleration. All you need to do is to figure out what that angle is, and then use the quaternion class to compute the position of vectors when rotated about your rotation vector by the angle you've computed.

Given a constant angular acceleration α, an initial angular velocity ω(t0) and initial angular position θ(t0) in the range [0, 2π) the angular position at some time t > t0, θ(t) is given by:

θ(t) = [θ(t0) + ω(t0)*(t-t0) + α*(t-t0)2/2] mod 2π

Here the mod 2π operation is simply the residual when subtracting n2π where n is the integer required to ensure the residual is in the range [0, 2π). For a constant angular velocity (i.e. α=0) the last term drops out.

That said, all you really need to do is to keep track of the angle over some interval of time under constant acceleration (or determine the average acceleration over that time if it's not constant) and update the angle. You then apply the resulting rotation about your rotation vector to the quaternion you're using to accumulate your rotations. This can be easily implemented as a C++ class.

Still, if you're looking for an open source tool to do this, I expect that any of the game physics modeling libraries will be more than adequate. A couple of open source ones are Bullet and the Open Dynamics Library.

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There is no function for converting to quaternions from angular velocity.. –  maximus Sep 27 '10 at 2:24
@maximus: I updated my answer to better address your concern. –  andand Sep 27 '10 at 13:53
Thank you very much! Very useful information. –  maximus Sep 27 '10 at 17:00
One question about what you've written above, I know the angular velocity and initial angular position at time t0. Then as you said I calculate the next angle rotations using data about angular velocity and using that formula, at this step everything is OK. But one more step further. Actually how to keep records and at each time to know the angular position of the object relatively to the coordinate system at time t0? –  maximus Sep 27 '10 at 17:07
@maximus: There's some additional book-keeping you'll need to manage that will be abstracted inside your C++ class. This includes t0, your initial angular position, angular velocity, and if necessary the angular acceleration as well. You apply the equation whenever asked to determine the angular position of your rotation; you don't actually need to change any of the parameters (unless you want to). But, any time you do change the position or the velocity (or acceleration), you should also provide the new t0 that applies to those new values. –  andand Sep 27 '10 at 18:02

Would you be talking about a Slerp? (Spherical Linear Interpolation)

See Jonathan Blow's article "Understanding Slerp, Then Not Using It" which has example source in C++...


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What language? E.g. for Python cgkit has a nifty quat module (quaternions initialized from a rotation matrix, not "an angular velocity", but presumably you can build the former from the latter?) and euclid.py has Python source code for a Quaternion class including class methods to build it from rotation matrix and in other ways.

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Each sample from your gyroscopes represents a small rotation:

rot_x = angV_x * timestep
rot_y = angV_y * timestep
rot_z = angV_z * timestep

If the resulting rotations are small, you can convert this directly into a quaternion by taking half the rotation angle:

// for small rotations, quick & dirty quaternion is sufficient
// (note: all angles *must* be in radians!)
float k = timestep * 0.5;
quaternion raw_delta_Q(1.0, angV_x*k, angV_y*k, angV_z*k);  // unnormalized!

// combine rotation for current timestep with orientation state
estimated_orient_Q *= raw_delta_Q;  // multiply by unnormalized delta
estimated_orient_Q *= 1 / norm(estimated_orient_Q);  // then renormalize it!

If your rotations are larger than a few degrees, or if you need maximum accuracy, you will need to pay closer attention to how you get your quaternion.

EDIT: Note that the above code assumes *= is defined to do quaternion multiplication by both quaternions and real scalars. Some form of these functions (as well as the obvious constructor) will be present in any reasonable quaternion library.

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