# Real-life case (helps understand the question)

I am building a device that can freely rotate around all its axis (x, y, z) and is equipped with:

- an
**accelerometer**(A) that gives me a vector pointing to the centre of the Earth (Va) - a 3D
**magnetometer**(M) that gives me the direction of the magnetic field of the Earth (Vm)

The two vectors share the same reference system (x, y, z), but what I am interested to find is **the vector that points to the north relative to the Earth surface** [think of a hand-held compass: I want to find where the needle should point to].

**This video** shows a "ball compass" that has pretty much the same behaviour that my device should replicate electronically.

# The coding question

I did a bit of research, and it seems to me that I should use is **3D rotation matrices** doing the following two steps:

**rotate the reference system of Vm from R to R'**, in such a way that y' will be parallel to Va,**"flatten" the Vm vector**setting its y' component to 0

Unluckily I am still confused on how I should proceed in concrete terms (I have no previous experience of working with vectors and matrices). One of the things that confuses me is that most of the material I could google, talks in terms of angles, but **the data I am receiving from both sensors is in the form V(Vx, Vy, Vz)**, where Vz, Vy and Vz are the components of V along the reference system.

So my question really boils down to: **what is the matrix I have to use in order to perform the transformation of which at step #1?**

Thank you in advance for your time and expertise.