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Lots of posts talk about the gyro drift problem. Some guys say that the gyro reading has drift, however others say the integration has drift.

  1. The raw gyro reading has drift[link].
  2. The integration has drift[link](Answer1).

So, I conduct one experiment. The next two figures are what I got. The following figure shows that gyro reading doesn't drift at all, but has the offset. Because of the offset, the integration is horrible. So it seems that the integration is the drift, is it? enter image description here

The next figure shows that when the offset is reduced the integration doesn't drift at all. enter image description here

In addition, I conducted another experiment. First, I put the mobile phone stationary on the desk for about 10s. Then rotated it to the left then restore to back. Then right and back. The following figure tells the angle quite well. What I used is only reducing the offset then take the integration.

enter image description here

So, my big problem here is that maybe the offset is the essence of the gyro drift(integration drift)? Can complimentary filter or kalman filter be applied to remove the gyro drift in this condition?

Any help is appreciated.

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3 Answers 3

up vote 4 down vote accepted

If the gyro reading has "drift", it is called bias and not drift.

The drift is due to the integration and it occurs even if the bias is exactly zero. The drift is because you are accumulating the white noise of the reading by integration.

For drift cancellation, I highly recommend the Direction Cosine Matrix IMU: Theory manuscript, I have implemented sensor fusion for Shimmer 2 devices based on it.

If you insist on the Kalman filter then see kalman filtering for programmers.

By why are you implementing your own sensor fusion algorithm?

Both Android (SensorManager under Sensor.TYPE_ROTATION_VECTOR) and iPhone (Core Motion) offers its own.

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Really helpful, thanks! Actually, I'm know little about the white noise, I seems that the white noise has minor effect on the integration from the third diagram, is it? So is the drift really a serious issue? –  Allen Jee Jan 8 '13 at 11:44
Yes, the error can become arbirarily large due to the white noise. Of cource, if you have bias, the situation is even worse :( Anyway, upvoted your question! –  Ali Jan 8 '13 at 11:55
Appreciated :) I really want to see the the error due to the white noise to get some sense of how to calibrate it. Should I collect the gyro data in 1 hour or others? –  Allen Jee Jan 8 '13 at 12:09
@AllenJee If you collect the data for an 1 hour, you will see that the bias is fluctuating. Otherwise, I recommend the Direction Cosine Matrix IMU: Theory manuscript, it will give you a clear understanding of the issue. It's basically a tutorial. Good luck! –  Ali Jan 8 '13 at 12:21

In this discussion both Ali and Stefano have raised two fundamental aspects of drifts due to ideal integration.

Basically zero mean white noise is an idealized concept and even for such ideal noise integration offer higher gain over lower frequency component of noise, which introduces a low frequency drift in the integrated signal. By theory the zero mean noise should not cause any drift iff observed over significantly long time but practically ideal integration never works.

On the other hand, even a minor dc-offset in the reading (input signal) can cause a significant drift over a time, if an ideal integration (loss-less summation) is performed on it. It can ramp up a very small dc-offsets in the system, as ideal integration has infinite gain on DC component of an input signal. Therefore for the practical purpose we substitute ideal integration by a low pass filter whose cut-off can be as low as required but can not be zero or too low for practical purpose.

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The dear Ali wrote something that is really questionable and imprecise (wrong).

The drift is the integration of the bias. It is the visible "effect" of bias when you integrate. The noise - any kind of stationary noise - that has mean zero, consequently has integral zero (I am not talking of the integral of PSD, but of the additive noise of the signal integrated in time).

The bias changes in time, as a function of voltage and exercise temperature. E.g. if voltage changes (and it changes), bias changes. The bias it is not fixed nor "predictable". That is why you can not eliminate bias using the proposed subtraction of the estimated bias by the signal. Also any estimate has an error. This error cumulates in time. If the error is lower, the effects of cumulation (the drifting) become visible in a longer interval, but it still exists.

Theory says that a total elimination of bias it is not possible, at the present days. At the state of the art, no one has still found a way to eliminate the bias - based only gyroscopes and accelerometers magnetometers - that could filter all the bias out.

Android and iPhone have limited implementations of bias elimination algorithms. They are not totally free by bias effects (e.g. in small intervals). For some applications this can cause severe problems and unpredictable results.

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"The noise - any kind of stationary noise - that has mean zero, consequently has integral zero." Are you familiar with the concept of random walk? Or to put it in another way, if you toss a coin 100 times, according to your logic, I get exactly 50 heads and 50 tails. Do you see the problem? I suggest you revise your answer. –  Ali Jul 24 '13 at 8:09
He probably meant that the mean value of the integral is zero, too. Drift is a systematic tendency in a process. I am no expert in this, but I do not see any way to compensate for the integrated noise. The integrated bias, on the other hand, could be cancelled by on-the-fly recalibration based on detection of prolonged periods of near-zero angular acceleration. –  Pavel Bazant Dec 3 '13 at 12:36

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