The following is the representation for rotating about a unit quaternion {q0,q1,q2,q3} by an angle alpha:

```
q_0=cos(alpha/2)
q_1=sin(alpha/2)cos(beta_x)
q_2=sin(alpha/2)cos(beta_y)
q_3=sin(alpha/2)cos(beta_z)
```

Here,beta_x, beta_y and beta_z are the direction cosines of the unit quaternion, i.e. the axis about which I am rotating.

The rotation matrix corresponding to this is as follows: Let's call this **R1**

```
1- 2(q_2^2 + q_3^2) 2(q_1 q_2 - q_0 q_3) 2(q_0 q_2 + q_1 q_3)
2(q_1 q_2 + q_0 q_3) 1 - 2(q_1^2 + q_3^2) 2(q_2 q_3 - q_0 q_1)
2(q_1 q_3 - q_0 q_2) 2( q_0 q_1 + q_2 q_3) 1 - 2(q_1^2 + q_2^2)
```

Now, suppose my rotation matrix is represented by using Euler angles instead: Let's call this **R2**

R2 rotates a vector by phi around x axis first, then by theta around the y axis and finally by psi around the z axis. Now, suppose my axis of rotation is in the y-z plane.This means that there is no rotation around the x-axis, only a combination of rotations around the y and z axes. **This means that phi is zero**, which means that **R2(3,2) is zero.**

Alternatively, this also means that cos(beta_x) is zero, since there is no rotation about the x-axis.This means that q_1 is zero.**However, if we look at R1(3,2), it is not zero, unlike R2(3,2).Why are these two representations not the same? What am I missing?**

TL;DRMost likely you run into the so-called double cover issue, see for example Incorrect conversion from quaternions to euler angles and back. Please check. – Ali Jun 25 '13 at 13:01