Remove gravity from raw accelerometer data of IMU--> please approve math and algo

I am using this device (http://www.sparkfun.com/products/10724) and have successfully implemented an quite well working orientation estimation based on a fusion of magnetometer, accelerometer and gyroscope data based on this http://www.x-io.co.uk/node/8#open_source_imu_and_ahrs_algorithms implementation. Now I want to calculate the dynamic acceleration (measures acceleration without static gravity acceleration). For doing this I came to the following idea.

Calculate a running average of the raw accelerometer data. If the raw acceleration is stable for some time (small difference between running average and current measured raw data) we assume the device does not move and we are measuring the raw gravity. Now save the gravity vector and also current orientation as quaternion. This approach assumes that our device could not be accelerated constantly without gravity.

For calculating the acceleration without gravity I am now doing following quaternion calculation:

``````RA = Quaternion with current x,y,z raw acceleration values
GA = Quaternion with x,y,z raw acceleration values of estimated gravity
CO = Quaternion of current orientation
GO = saved gravity orientation

DQ = GO^-1 * CO // difference of orientation between last gravity estimation and current orientation

DQ = DQ^-1 // get the inverse of the difference

SQ = DQ * GA * DQ^1  // rotate gravity vector

DA = RA - SQ // get the dynamic acceleration by subtracting the rotated gravity from the raw acceleration
``````

Could someone check if this is correct? I am not sure because on testing it I get some high acceleration on rotating my sensor board, but I am able to get some acceleration data (but is is much smaller than the accelration during rotation) if the device is moved without rotating it.

Moreover I have the question if the accelerometer is also measuring acceleration if it is rotated on place or not!

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I am afraid I am missing an important point here. If you have get the orientaion after sensor fusion (and you say you already have it) then why don't you just substract the gravity from the measured acceleration? You cannot do better than that. I am afraid I am missing something here, so please explain. – Ali May 29 '12 at 15:45
I only have the relative orientation of the device seen from an arbitrary start point, I do not know the current position in world space. That is why I am estimating the gravity with above algorithm. – chris LB May 29 '12 at 19:48

It's easier than you think. You may wanna have a look at my post here about it: http://www.varesano.net/blog/fabio/simple-gravity-compensation-9-dom-imus

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Thank you for the answer! I have already found your post before, can you explain what the calculation in the function does? Do you assume we now the absolute orientation in world coordinates or how does it work? – chris LB Aug 1 '12 at 12:15
What if you have only 6dof IMU (no magnetometer) - can I still use this somehow? I get the quaternion from Extended Kalman Filter which was implemented by someone else. – Primož 'c0dehunter' Kralj Sep 27 '12 at 12:41
What's `q[3]` supposed to be in your code? AFAIK, 3D vectors have 3 coordinates... – Tomáš Zato Oct 20 '15 at 10:14

Another way is to differentiate accel to give jerk (using finite difference, j = (a2 - a1) / dt). Run the jerk through a decay/leakage function (use a half life decay calc value rather than a simple multiplier). Then integrate the jerk (trapezoidal rule, a = dt * (j1 + j2) * 0.5) and it will remove the DC offset (gravity). Again run this signal through a decay function.
The decay functions avoid the value spiraling off but will reduce the magnitude of dynamic acceleration values that you see and will introduce some shaping to the signal. So you won't get values that are 'accurate' m/s/s readings any longer. But it is useful for short-time movements.

Of course you could just use a highpass filter instead but that generally requires a fixed sampling rate and is probably more computationally expensive if you are using convolution (finite impulse response filter).

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