# Calibrating 3d Accelerometer for 2d Game

I am making a 2d game. The phone is held horizontally and a character moves up/down & left/right to avoid obstacles. The character is controlled by the accelerometer on the phone. Everything works fine if the player doesn't mind 0,0 (the point where the character stands still) being when the phone is held perfectly flat. In this scenario it's possible to just read the Y and X values directly and use them to control the character. The accelerometer values are between -10 and 10 (they get multiplied by an acceleration constant to decide the movement speed of the character), libgdx is the framework used.

Thep problem is that having 0,0 isn't very comfortable, so the idea is to calibrate it so that 0,0 will be set to the phones position at a specific point in time.

Which brings me to my question, how would I do this? I tried just reading the current X and Y values then subtracting it. The problem with that is that when the phone is held at a 90 degree angle then the X offset value is 10 (which is the max value) so it ends up becoming impossible to move because the value will never go over 10 (10-10 = 0). The Z axis has to come into play here somehow, I'm just not sure how.

Thanks for the help, I tried explaining as best as I can, I did try searching for the solution, but I don't even know what the proper term is for what I'm looking for. Any help would be appreciated.

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For a simple solution you can look at the methods:

``````Gdx.input.getAzimuth(), Gdx.input.getPitch(), Gdx.input.getRoll()
``````

The downside is that those somehow use the internal compass to give your devices rotation compared to North/South/East/West. I did only test that very shortly so I'm not 100% sure about it though. Might be worth a look.

The more complex method involves some trigonometry, basically you have to calculate the angle the phone is held at from `Gdx.input.getAccelerometerX/Y/Z()`. Must be something like (for rotation along the longer side of the phone):

``````Math.atan(Gdx.input.getAccelerometerX() / Gdx.input.getAccelerometerZ());
``````

For both approaches you then store the initial angle and subtract it later on again. You have to watch out for the ranges though, I think `Math.atan(...)` is within `-Pi` and `Pi`.

Hopefully that'll get you started somehow. You might search for "Accelerometer to pitch/roll/rotation" and similar, too.

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An old question, but I am providing the answer here as I couldn't find a good answer for Android or LibGDX anywhere. The code below is based on a solution someone posted for iOS (sorry, I have lost the reference).

You can do this in three parts:

1. Capture a vector representing the neutral direction:

``````Vector3 tiltCalibration = new Vector3(
Gdx.input.getAccelerometerX(),
Gdx.input.getAccelerometerY(),
Gdx.input.getAccelerometerZ() );
``````
2. Transform this vector into a rotation matrix:

``````public void initTiltControls( Vector3 tiltCalibration ) {
Vector3.tmp.set( 0, 0, 1 );
Vector3.tmp2.set( tiltCalibration ).nor();
Quaternion rotateQuaternion = new Quaternion().setFromCross( Vector3.tmp, Vector3.tmp2 );

Matrix4 m = new Matrix4( Vector3.Zero, rotateQuaternion, new Vector3( 1f, 1f, 1f ) );
this.calibrationMatrix = m.inv();
}
``````
3. Whenever you need inputs from the accelerometer, first run them through the rotation matrix:

``````public void handleAccelerometerInputs( float x, float y, float z ) {

Vector3.tmp.set( x, y, z );
Vector3.tmp.mul( this.calibrationMatrix );

x = Vector3.tmp.x;
y = Vector3.tmp.y;
z = Vector3.tmp.z;

[use x, y and z here]
...
}
``````
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