I am developing application for car acceleration tracking. I used standard accelerometer, calibrating it in specific position beforehand.

Then, assuming phone's orientation is not changing, I logged the accelerometer data for a specified time and calculated move parameters, one of which is the car's speed at the end of the test.

It works rather well, on a straight, horizontal road: error of a few percent.

But then I found out, that in API-level 10 there is a virtual sensor called TYPE_LINEAR_ACCELERATION and, as far as I understand, it must do what I need: filter gravity, orientation changes - so I may use it and get pure linear acceleration of mobile device.

BUT in real life..

I made a simple application, that does a little test:

//public class Accelerometer implements SensorEventListener { ...
public void onSensorChanged(SensorEvent se) 

    lastX = se.values[SensorManager.DATA_X];
    lastY = se.values[SensorManager.DATA_Y];
    lastZ = se.values[SensorManager.DATA_Z];
    long now = System.currentTimeMillis();
    interval = now - lastEvetn;
    lastEvetn = now;
    out.write(Float.toString(lastX) + ";" + 
                    Float.toString(lastY) + ";" + 
                    Float.toString(lastZ) + ";" + 
                    Long.toString(interval) + "\n");

I bind a listener with the following parameters:


It works OK, but when I analyzed data dump, calculating speed like V = V0 + AT, where V0 = 0 at first, then - speed of interval before this, A = acceleration (SQRT (x*x+y*y+z*z)) (t = time of interval), eventually I get a very low speed - three times less than real speed.

Changing Sensor type to TYPE_ACCELEROMETER, calibrating and using same formula to calculate speed - I get good results, much closer to reality.

So, the question is:

What does Sensor.TYPE_LINEAR_ACCELERATION really show?

Where am I wrong, or is something wrong with Sensor.TYPE_LINEAR_ACCELERATION implementation?

I used Samsung Nexus S phone.

  • Very interesting! The Sensor.TYPE_LINEAR_ACCELERATION does exactly what you write. Why do you compute the length of the acceleration (SQRT (xx+yy+z*z)? How well did you test your previous method? Just a few measurements? What I find really interesting is that your previous method produces fairly precise results. These sensors can track velocity for less than a second, that is why I am surprised. Even though it is for position, the velocity isn't any better, see link. – Ali Oct 22 '11 at 17:56
  • Hi. If sensor shows acceleration in x,y,z directions, then value of A is SQRT(xx+yy+z*z). If sensor shows something other - that is the question. what it shows? – Maep Oct 23 '11 at 1:35
  • If sensor shows something other - that is the question. what it shows? My previous method was tested many times, with different speeds. In car, where position of phone is well fixed - it works rather accurate, it NEVER give mistake more then 10%. It's a result, i think. That why i dont't understand - why linear accelerometer behaves so strange... If you are interested in, i can send you source code of working method. – Maep Oct 23 '11 at 1:42
  • 1
    You understood linear acceleration correctly, it is exactly what you wrote. I still do not understand why you need SQRT(xx+yy+z*z). Please check my code, from lines 134 and 148, v0 is initial velocity, v is velocity. The length of the acceleration is never needed when you compute velocity, so please post your code showing why you use it. – Ali Oct 23 '11 at 7:28
  • 1
    OK, my mistake, I did not understand that part, sorry. – Ali Oct 26 '11 at 7:16

Very interesting question!!!!

I'm developing somethig similar to your application. What i found about TYPE_LINEAR_ACCELERATION isn't happy for me.

1) TYPE_LINEAR_ACCELERATION, TYPE_GRAVITY, ecc are implemented only for Android 2.3 (and up) So i have Android 2.2 and i can't test them.

2) TYPE_LINEAR_ACCELERATION isn't so accurate as it would be, because there are some simple problem when substract the gravity. In fact is a "sensor fusion" that uses accelerometer and orientation to know where is directed the gravity and then subs. it.

Here i found a very usefull answer that explain it:


TYPE_ACCELEROMETER uses the accelerometer and only the accelerometer. It returns raw accelerometer events, with minimal or no processing at all.

TYPE_GYROSCOPE (if present) uses the gyroscope and only the gyroscope. Like above, it returns raw events (angular speed un rad/s) with no processing at all (no offset / scale compensation).

TYPE_ORIENTATION is deprecated. It returns the orientation as yaw/ pitch/roll in degres. It's not very well defined and can only be relied upon when the device has no "roll". This sensor uses a combination of the accelerometer and the magnetometer. Marginally better results can be obtained using SensorManager's helpers. This sensor is heavily "processed".

TYPE_LINEAR_ACCELERATION, TYPE_GRAVITY, TYPE_ROTATION_VECTOR are "fused" sensors which return respectively the linear acceleration, gravity and rotation vector (a quaternion). It is not defined how these are implemented. On some devices they are implemented in h/w, on some devices they use the accelerometer + the magnetometer, on some other devices they use the gyro.

On Nexus S and Xoom, the gyroscope is currently NOT used. They behave as if there was no gyro available, like on Nexus One or Droid. We are planing to improve this situation in a future release.

Currently, the only way to take advantage of the gyro is to use TYPE_GYROSCOPE and integrate the output by hand.

I hope this helps,


Anyway, in various place on the web i found no best word about phone sensor and their potential, due to the fact that aren't accurate...

Some more precision can be reached using Kalman filter, but i have no idea how...

  • i have android 2.3.4, but linear acceleration does not work. anyway, accelerometer makes pretty good results. I compare it with GPS, and i can say - for short-time data requesting, accelerometer is better: GPS has lags and is not refreshed frequently. Look at my graph here: blue is accelerometer data, red - GPS, black label - car speed at the end of experiment checked by speedometer. I continue working on that method to improve accuracy img84.imageshack.us/img84/6991/accpn.png – Maep Nov 21 '11 at 13:55
  • @Maep : you seem to get good result from accelerometer. Could you please help me out here - stackoverflow.com/questions/12926459/… – Ashwin Oct 17 '12 at 3:47
  • Helpful, but not usable with NDK. In the NDK there does not seem to be a GRAVITY type. There is ASENSOR_TYPE_ACCELEROMETER but no ASENSOR_TYPE_GRAVITY. Some sources warn against getting it in JAVA and lobbing it to C via JNI, as it eats far too much battery. – Bram Jul 16 '14 at 2:13
  • @Lork do you know how to detect the moviment of TOP to Bottom? I mean like smash your device? – Skizo-ozᴉʞS Jan 25 '16 at 15:21

I realize my answer is pretty late. I bumped into this thread while hunting for some info on TYPE_LINEAR_ACCELERATION.

It is not right to do a = sqrt(ax^2+ay^2+az^2) and then do v=u+at. That will work only when v and a are in the exact same direction. And any deviation would make the errors add up. Acceleration and velocity are vector quantities, and should be treated as such. You should do vx=ux+axt, vy=uy+ayt and vz=uz+azt. and then v= sqrt(vx^2+vy^2+vz^2).

  • what ux, axt, uy, ayt, uz, azt, vx,vy and vz variables are? what represent every one? – angel Aug 16 '16 at 18:54
  • ux is x component of initial velocity. ax is x component of acceleration. vx is x component of final velocity, And so on – sudP Aug 17 '16 at 1:17

TYPE_LINEAR_ACCELERATION doesn't show the "raw" data from the sensor, it shows data that was processed by hi-frequency filter, so the constant acceleration like gravity or any other slowly changing acceleration cannot pass through the filter.

Your car has pretty constant acceleration that cannot pass the filter. If you change your acceleration very fast pressing the brakes then pressing the accelerometer pedal then back to the brakes then TYPE_LINEAR_ACCELERATION would show the pretty correct result, otherwise it always shows less then the real acceleration value.

Use TYPE_ACCELEROMETER and then remove G (9.81) manually. Actually, you have to measure G yourself when the real acceleration is 0 and then use TYPE_ACCELEROMETER value as G. In my case it is 9.6.

TYPE_ACCELEROMETER is good for the fast changing acceleration that lasts less then 1 second like moving you hand emulating a box or sword fighting.


TYPE_LINEAR_ACCELERATION is a three dimensional vector indicating acceleration along each device axis, not including gravity. TYPE_ACCELEROMETER = TYPE_GRAVITY + TYPE_LINEAR_ACCELERATION

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