The direction of the "fall-line" and the magnitude of the acceleration are both determined by the projection of the gravitational pull vector onto the plane. If the plane has a normal vector **n**, then the projector operator is **P**( **n** ) = **1** - **nn**, where **1** is the identity operator and **nn** is the outer (tensor) product of the normal vector with itself. The projection of the gravitational pull vector **g** is simply **g**' = **P**( **n** ).**g** = (**1** - **nn**) **g** = **g** - (**n** . **g**) **n**, where the dot denotes inner (dot) product. Now you only have to choose a suitable orthonormal reference frame (**ex**, **ey**, **ez**), where **ei** is a unit vector along direction *i*. In this reference frame:

**n** = nx **ex** + ny **ey** + nz **ez**

**g** = gx **ex** + gy **ey** + gz **ez**

The dot product **n** . **g** is then:

**n** . **g** = nx * gx + ny * gy + nz * gz

A very suitable choice of a reference frame is one where **ez** is collinear with **n**. Then nx = 0 and ny = 0 and nz = ||**n**|| = 1, because normal vectors are of unit length. In this frame **n** . **g** is simply gz. The components of the projection of **g** are then:

g'x = gx

g'y = gy

g'z = 0

The direction of **g**' in the XY plane can be determined by the fact that for the dot product in orthonormal reference frames **a** . **b** = ||**a**|| ||**b**|| cos(**a**, **b**), where ||**a**|| denotes the norm (length) of **a** and cos(**a**, **b**) is the cosine of the angle between **a** and **b**. If you measure the angle from the X direction, then:

**g**' . **ex** = (gx **ex** + gy **ey**) . **ex** = gx = ||**g**'|| ||**ex**|| cos(**g**', **ex**) = g' cos(**g**', **ex**)

where g' = ||**g**'|| = sqrt(gx^2 + gy^2). The angle is simply arccos(gx/g'), i.e. arc-cosine of the ratio between the X component of the gravity pull vector and the magnitude of its projection onto the XY plane:

angle = arccos[gx / sqrt(gx^2 + gy^2)]

The magnitude of the acceleration is proportional to the magnitude of **g**', which is (once again):

g' = ||**g**'|| = sqrt(gx^2 + gy^2)

Now the nice thing is that all accelerometers measure the components of the gravity field in a reference frame that usually have **ex** aligned with the height (or the width) of the device, the **ex** aligned with the width (or the height) of the device and **ez** is perpendicular to the surface of the device, which matches exactly the reference frame, where **ez** is collinear with the plane normal. If this is not the case with your Arduino device, simply rotate the accelerometer and align it as needed.