How would one convert an inclinometers (Pitch, Yaw and Roll) into the gravitational pull expected on the system in `[X,Y,Z]`

?

A system at rest in a certain Pitch, Yaw and Roll angle should be pulled to earth at a certain `[X*g,Y*g,Z*g]`

, lets say this is for simulation purposes. I want to make a function whoose input is Pitch, Yaw and Roll and the output is a `Vector3(X,Y,Z)`

of the downard moment.

Meaning a object at rest with it's back downwards would output something like `[0,-1,0]`

from the accelerometers and a `[pitch,yaw,roll]->[0,-1,0]`

, where `[0,-1,0]`

minus `[0,-1,0]`

resulting in `[0,0,0]`

. or if we pull it left at the speed 1g we have a accelerometer showing `[1,-1,0]`

making the new value `[1,0,0]`

.

**With the system on its back [pitch,yaw,roll]->[0,-1,0] function is what i'm after**

```
Vector3 OriToXYZ(float pitch, float yaw, float roll){
Vector3 XYZ = Vector.Zero;
//Simulate what the XYZ should be on a object in this orientation
//oriented against gravity
...
return XYZ;
}
```

Yes I know as the explanation below shows I'm not able to detect if the systems upside down or not based on the roll as roll only gives (-90 to 90) but that's a different problem).

This is how the orientation is laid out.

**For extra information about why, what and how to use this information keep reading.**

The plan is to use the incinometer as an alternative to the gyrometer for removing the gravity component to the accelerometer data, by simulating/calculating the expected value of gravity at orientation (Pitch,Yaw,Roll).

As the accelerometer(XYZ) is a combination of two components gravity(XYZ) and movement(XYZ), I'm assuming that `gravity(XYZ)-calc_g(XYZ) = 0,`

allowing me to perform `accelerometer(XYZ)- calc_g(XYZ) =movement(XYZ)`

to show why i think this is possible. when i graph the values from the phone and move the phone sideways hard in a somewhat pendulum motion the lines that looks like sine/cosine motions are inclinometre and the other lines are XYZ accelerometer:

- red = (Pitch & accell-X)
- green = (Yaw & accell-Y)
- blue = (Roll & accell-Z)

Acceleration value is multiplied by 90 as it ranges from (-2 to 2) so that it in the drawing ranges from -180 to 180, Pitch yaw and roll ranges as seen in the instructable above. The middle of the image is Y = 0, left side is X=0 (X=time)

**Solved
Solution by Romasz**

```
VectorX = Cos(Pitch)*Sin(Roll);
VectorY = -Sin(Pitch);
VectorZ = -Cos(Pitch)*Cos(Roll);
```

**Result**

*The graphs are not from the same measurement.

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