# calculate acceleration in reference to true north

For my App I need to calculate the acceleration of my device in reference to true north. My idea was to calculate the device orientation to magnetic north and apply the declination to it to get the orientation to true north. Then I want to calculate the acceleration of the device and reference it to the orientation, but I do not know how I should do this.

I would try to get the device orientation using `SensorManager.getRotationMatrix()` and `SensorManager.getOrientation()`. Then I get the declination by `GeomagneticField.getDeclination()`and apply it on the azimuth of the orientation values from `SensorManager.getOrientation()`.

But how do I map the accelerometer values to this orientation? Is it even possible?

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If I understood you correctly, what you are saying is if the device is moving toward the West or East then the accelerator value in this case should be 0, am I right? –  Hoan Nguyen Feb 20 '13 at 4:32
No, I need to remap the axis of the accelerometer in that way, that when the device (i.e.) is moving north, the y-value is positive and moving south it is negative. And when moving east the x- value is positive and when moving west it is negative. The z-value is currently not needed. I think I found a good source in this question: stackoverflow.com/questions/11578636/… –  htz Feb 20 '13 at 12:01
Of course, when there is a constant motion towards any direction, the values should be 0, because there is no acceleration measureable. –  htz Feb 20 '13 at 12:13
All the calculations in the solution in the above link seem unnessaire. See my solution below. –  Hoan Nguyen Feb 20 '13 at 19:30

The accelerometer sensor returns the acceleration of the device. This is a vector in 3 dimentional space. This vector is returned in the device coordinate system. What you want is the coordinate of this vector in the world coordinate, which is simply

``````R = rotation matrix obtained by calling getRotationMatrix
A_D = accelerator vector return by sensor ( A_D = event.values.clone )
A_W = R * A_D is the same acceleration vector in the world coordinate system.

A_W is an array of dimention 3
A_W[0] is acceleration due east.
A_W[1] is acceleration due north.
``````

Here is some code to compute it (assumes `gravity` and `magnetic` contain output from their respective sensors):

``````            float[] R = new float[9];
float[] I = new float[9];
SensorManager.getRotationMatrix(R, I, gravity, magnetic);
float [] A_D = values.clone();
float [] A_W = new float[3];
A_W[0] = R[0] * A_D[0] + R[1] * A_D[1] + R[2] * A_D[2];
A_W[1] = R[3] * A_D[0] + R[4] * A_D[1] + R[5] * A_D[2];
A_W[2] = R[6] * A_D[0] + R[7] * A_D[1] + R[8] * A_D[2];
``````
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I believe your answer may be wrong (see my comment in the accepted answer in stackoverflow.com/questions/11578636/…) –  ravemir Apr 16 '13 at 18:36
No, if you really understand what the rotation matrix is and look at how it is calculate in the source code. It is just the change of basis matrix from the device coordinate system to the world coordinate system. –  Hoan Nguyen Apr 16 '13 at 18:40
This [link] (gentlenav.googlecode.com/files/DCMDraft2.pdf) provides an explanation of the rotation matrix, and reports the World Coords as the product of the Rotation Matrix and the Plane Coords. Given that, the rotation matrix computed by Android may be one that maps Device to World (the reverse of the example), but how can you know for sure? –  ravemir Apr 16 '13 at 18:54
That is in the source code. –  Hoan Nguyen Apr 16 '13 at 18:56
In the android-sdk --> sources --> android-17 --> android --> hardware --> SensorManager. Or any android-number you want instead of 17 –  Hoan Nguyen Apr 16 '13 at 19:04