You can try to construct quaternions directly from yaw/pitch:

```
q = quat_from_axis_angle(up_vector, yaw) * quat_from_axis_angle(local_right, pitch)
```

(you may have to multiply these in the reverse order depending on how exactly you turn them into rotation matrices), or realign them every time you change them:

```
rotated_right = apply_rotation(q, local_right);
projected_right = rotated_right - dot(rotated_right, up_vector) * up_vector;
realign = quat_align_vector(rotated_right, normalized(projected_right));
q = realign * q
```

`projected_right`

here is a projection of `rotated_right`

onto the horizontal plane. Without rolling, these two vectors must be the same, which implies `dot(rotated_right, up_vector) = 0`

. The last equation is the actual constraint that must be satisfied. It is quadratic in `q`

. E.g. for `local_right=(1,0,0)`

, and `up_vector=(0,0,1)`

, it becomes `dot(q*(1i+0j+0k)*conj(q), 0i+0j+1k)=2*x*z-2*w*y=0`

, with `q=w+xi+yi+zk`

.

You can find formulas for `quat_from_axis_angle`

and `apply_rotation`

at http://en.wikipedia.org/wiki/Quaternion and http://en.wikipedia.org/wiki/Quaternions_and_spatial_rotation. As for `quat_align_vector`

, one way would be

```
quat_align_vector(src, dst) = sqrt([dot(src, dst), cross(src, dst)])
```

with `[a, b]`

beign a quaternion with a real part `a`

, and an imaginary part `b`

. `Sqrt(x)`

can be calculated as `exp(ln(x)/2)`

(these functions are on the wiki, too). You could also try replacing sqrt with `exp(ln(x)/2*tick*realign_rate)`

for a smooth restoration of the up-vector :) . Or go the opposite way and simplify the formula a bit:

```
quat_align_vector(src, dst) = [dot(halfway, dst), cross(halfway, dst)],
halfway = normalized(normalized(src) + normalized(dst))
```

See also http://stackoverflow.com/a/1171995.

EDIT: corrected vectors, added the constraint.