# Vertical movement sensor

I am working on an android app that requires the detection of vertical motion. When moving the tablet upward, the Gyroscope, Accelerometer, and Linear Acceleration sensors give a corresponding value indicating upward or downward motion.

The problem I have is that these sensors will also read an upward/downward motion when you tilt the tablet towards the user or away from the user. For example, the x value in the gyroscope represents the vertical plane. But when you tilt the device forwards, the x value will change. When I make this motion, the same sensor that reads vertical motion reads a value for this. http://i.imgur.com/BHEx4.png

The same goes for the rest of the sensors. I have tried to use orientation coupled with the gyro to make the conditional statement, if the pitch is not changing, but the x variable is going up/down, then we have vertical motion. The problem with this is that if the user moves it up but tilted slightly, it will no longer work. I also tried making it so if there is a change in tilt, then there is no vertical motion. But it iterates so quickly that there may be a change in tilt for 1/100 of a second, but for the next there isn't.

Is there any way I can read only vertical changes and not changes in the devices pitch?

Here is what I want to detect: http://i.imgur.com/o0iAW.png

edit:

"Please come up with a mathematically sound definition of what you consider 'moving upwards.'" This was my initial question, how can I write a function to define when the tablet is moving upwards or downwards? I consider a vertical translation moving upwards. Now how do I detect this? I simply do not know where to begin, thank you.

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When a user tilts the tablet, there's an upward/downward motion. If what you want is detect the movement while the tablet is held vertical, then only look for vertical movement if the tablet is tilted from 90º (+-10º or whatever the margin you want to give). –  m0skit0 Nov 2 '12 at 19:30
But if the tablet is moved upward, but is tilted, then there will be no registered movement. Also, +-10 degrees is enough to mess with values of vertical movement. This is my last resort solution, I'd like something better and more reliable. –  user1795223 Nov 2 '12 at 19:39
I see some trig in your future. What should happen if the user tilts it 90 forward(parallel to horizon) and moves the tablet on its own vertical axis(forward/away from user)? What should happen if the tablet is "upside down" for lefties? What should happen if the tablet is held at 70 degrees, or a bit askew? All those conditions and more will affect "vertical" readings. Up/down movement isn't just up/down movement. It's going to take very careful design to get this working right in all/most situations. –  Geobits Nov 2 '12 at 19:53
I too have considered some of these things. I am using this motion to control a camera, so the tablet will always face the user. I do think there is a way to do this using vectors and trig to come out with just vertical motion, I just am unable to come up with these calculations. –  user1795223 Nov 2 '12 at 20:05
You can try and calculate deltas for each axis in a given time. When the vertical axis gets an N consecutive number of bigger delta increases than the other axis, you can assume vertical movement. –  m0skit0 Nov 2 '12 at 20:18

## 2 Answers

OK, I suspect it is only a partial answer.

If you want to detect vertical movement, you only need linear acceleration, the device orientation doesn't matter. See

iOS - How to tell if device is raised/dropped (CoreMotion)

or

how to calculate phone's movement in the vertical direction from rest?

For some reason you are concerned with the device orientation as well, and I have no idea why. I suspect that you want to detect something else. So please tell us more and then I will improve my answer.

UPDATE

I read the post on coremotion, and you mentioned that higher z lower x and y means vertical motion, can you elaborate?

I will write in pseudo code. You measured the `(x, y, z)` linear acceleration vector. Compute

``````rel_z = z/sqrt(x^2+y^2+z^2+1.0e-6)
``````

If `rel_z > 0.9` then the acceleration towards the z direction dominates (vertical motion). Note that the constant `0.9` is arbitrary and may require tweaking (should be a positive number less than 1). The `1.0e-6` is there to avoid accidental division by zero.

You may have to add another constraint that `z` is sufficiently large. I don't know your device, whether it measures gravity as 1 or 9.81. I assume it measures it as 1.

So all in all:

``````if (rel_z > 0.9 && abs(z) > 0.1) { // we have vertical movement
``````

Again, the constant `0.1` is arbitrary and may require tweaking. It should be positive.

UPDATE 2

I do not want this because rotating it towards me is not moving it upwards

It is moving upwards: The center of mass is moving upwards. My code has the correct behavior.

Please come up with a mathematically sound definition of what you consider "moving upwards."

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I don't care about orientation. It's just that the linear acceleration value for moving the tablet upwards and downwards also changes when I tilt it forwards and backwards(shown in my pictures). Therefore, I cannot reliably tell when it is moved upwards or downwards because the user could be simply be tilting it forwards or backwards. I read the post on coremotion, and you mentioned that higher z lower x and y means vertical motion, can you elaborate? Also, I've read that a high pass filter may help detect sudden movements, what exactly is this and how do I apply it to acceleration? Thank you –  user1795223 Nov 2 '12 at 22:12
Also, I fear that tilting forward/backward it may result in a high z value (as would moving it up/down) and thus render what you've said useless. –  user1795223 Nov 2 '12 at 22:17
I think I may have misunderstood your question about orientation. Let me explain my project: I have an ip camera, I am streaming video to a tablet. When I move the tablet, the camera moves in the same way. But if I move it up, while tilting the device, it can mess up the result because tilting changes the value that I read for upward movement. I only want upward movement. I do not want a slight tilt changing my value. I don't want changes in pitch to affect my numbers. –  user1795223 Nov 2 '12 at 22:23
@user1795223 OK, I updated the answer. It will require some tweaking but it should work. –  Ali Nov 2 '12 at 22:32
As a test I did this: float rel_z = (float) (z/Math.sqrt(xx+ yy+z*z+1.0e-6)); and the value comes to be around .57. x,y,z all come from linear acceleration sensor. rel_z never really changes except from negative to positive and a few decimals in the thousandths. I am leaving work now, but I'd like to continue this if I can on monday. I did this in a hurry so I may have made a mistake somewhere, but I don't think so. Thanks. –  user1795223 Nov 2 '12 at 22:53

Ok, even though this question is fairly old, I see a lot of confusion in the present answer and comments, so in case anyone finds this, I intend to clear a few things up.

# The Gyroscope

First of all, the gyroscope does not measure vertical motion as per your definition (a translatory motion). It measures rotation around each of the axes, which are defined as in the figure below. Thus having you tilt your device forwards and backwards indeed rotates it around the x axis and therefore you will see non-zero values in the x value of your gyroscope sensor.

the x value in the gyroscope represents the vertical plane.

I'm not sure what is meant by "the vertical plane", however the x value certainly does not represent the plane itself nor the orientation of the device within the plane.

The x value of the gyroscope sensor represents the current angular velocity of the device around the x axis (eg. the change in rotation).

But when you tilt the device forwards, the x value will change. When I make this motion, the same sensor that reads vertical motion reads a value for this.

Not quite sure what you're referring to here. "The same sensor that reads vertical motion" I assume is the gyroscope, but as previously said, it does not read vertical motion. It does exactly what it says on the tin.

# The device coordinate system

This is more in response to user Ali's answer than the original question, but it remains relevant in either case.

The individual outputs of the linear acceleration sensor (or any other sensor for that matter) are expressed in the coordinate system of the device, as shown in the image above. This means if you rotate the device slightly, the outputs will no longer be parallel to any world axis they coincided with before. As such, you will either have to enforce that the device is in a particular orientation for your application, or take the new orientation into account.

The `ROTATION_VECTOR` sensor, combined with quaternion math or the `getRotationMatrixFromVector()` method, is one way to translate your measurements from device coordinates to world coordinates. There are other ways to achieve the same goal, but once achieved, the way you hold your device won't matter for measuring vertical motion.

In either case, the axis you're looking for is the y axis, not the z axis.

(If by any chance you meant "along device y axis" as "vertical", then just ignore all the orientation stuff and just use the linear acceleration sensor)

# Noise

You mentioned some problems regarding noise and update rates in the question, so I'll just mention it here. The simplest and one of the more common ways to get nice, consistent data from something that varies very often is to use a low-pass filter. What type of filter is best depends on the application, but I find that a exponential moving average filter is viable in most cases.

# Finishing thoughts

Note that if you take proper care of the orientation, your transformed linear acceleration output will be a good approximation of vertical motion (well, change in motion) without filtering any noise.

Also, if you want to measure vertical "motion", as in velocity, you need to integrate the accelerometer output. For various reasons, this doesn't really turn out too well in most cases, although it is less severe in the case of velocity rather than trying to measure position.

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