# What exactly does the iPhone accelerometer measure?

The apple documentation for UIAcceleration class says, a "When a device is laying still with its back on a horizontal surface, each acceleration event has approximately the following values: x: 0 y: 0 z: -1"

Now, I am confused! How can the acceleration be non-zero, when you clearly say the "device is laying still"?

# UPDATE

Judging by the responses, I think this should be called something like 'forceometer' or 'gravitometer' and not accelerometer!

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So if you turn it around (on it's belly) it will measure x:0 y:0 z:+1 –  rokjarc Feb 15 '12 at 13:22
A comment to your update: the equivalence principle of the theory of general relativity will tell you that acceleration on a body is equivalent to gravitation (simply worded). So acceleratometer is, for me, as good as any term, though "forcemeter" would probably come closest to how the device actually works. Note that a gravimeter is actually a slightly different device. –  Evert Nov 30 '12 at 11:11
@Evert iOS reports the direction it would accelerate in the absence of an external force counteracting gravity. It would make more sense to measure that external force, but instead iOS confusingly presents a pseudo-acceleration gravity vector. Not only the ground's normal force counteracting gravity, but all forces are reversed. So maybe it should be called a decelerometer. –  Potatoswatter Dec 14 '12 at 6:58

You get a -1 on the Z axis because gravity is acting on the device, applying a constant acceleration of 1G. I assume you want user acceleration, which you can get from the DeviceMotion object using a device motion handler as opposed to an acceleration handler. The userAcceleration property filters out the effects of gravity on the device and only gives you how much the user is accelerating it.

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I am just trying to understand the concepts here. Even if the phone experiences a force due to gravity, when it is stationary there is no change in its velocity along any direction. So the acceleration should still be zero, right? –  gigahari Feb 15 '12 at 13:15
when stationary (or moving with constant speed in constant direction) it will measure (feel) 1g directed to the center of the earth. You should consider this 3 directions as vectors - their vectoral sum would be 1g and from their sizes you can calculate how the device is tilted. As Ali mentioned: it would measure 0 at free fall - when on table, it 'feels' the force of the table holding it in place :) –  rokjarc Feb 15 '12 at 13:19
Device is still being pulled by the gravity. The Force is there. Jedis know that more than anyone. –  macbirdie Feb 15 '12 at 13:20

You'll find the best answers in datasheet of the accelerometer used (LIS302DL).

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Link mentioned by @rokjarc is dead by now. Searching for CD00135460.pdf revealed following links: eng.auburn.edu, myavr.info and cs.smith.edu. –  trejder Jul 16 '13 at 10:14
@trejder: thank you, i edit the answer accordingly. –  rokjarc Jul 16 '13 at 10:36

It measures the gravity. The unit is chosen so that the gravity, 9.81 m/s^2, equals 1 unit. The sign tells how the phone axis is directed. In other words, what the phone considers downwards.

The phone measures 0 as acceleration in free fall. I don't know how much you want to throw your phone up and down to test it :)

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just to add the official doc's link: developer.apple.com/library/ios/documentation/coremotion/… –  Ikhsan Assaat Aug 13 at 23:35

I found the answer here so thanks @bensnider:

"The accelerometer measures the sum of two acceleration vectors: gravity and user acceleration. User acceleration is the acceleration that the user imparts to the device."

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When you're sitting, gravity is pulling you down to your chair. If it weren't for the chair or ground for that matter, you'd be falling down with acceleration of about 9.8m/s^2. In order for the chair to prevent you from falling down, it has to act with a force in the opposite direction with at least the same value.

The accelometer shows the value of the pulling force and it's a three-dimensional vector. In this case it's directed straight down. And the value given is expressed in G, units of gravity acceleration multiplied by that value.

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