I had the same problem recently, so I had a look at some of the THREE.*Controls files, similar to you.

Using those as a basis, I made this:
https://github.com/squarefeet/THREE.ObjectControls

The important bits are the following (see here for context):

```
var updateTarget = function( dt ) {
var velX = positionVector.x * dt,
velY = positionVector.y * dt,
velZ = positionVector.z * dt;
rotationQuaternion.set(
rotationVector.x * dt,
rotationVector.y * dt,
rotationVector.z * dt,
1
).normalize();
targetObject.quaternion.multiply( rotationQuaternion );
targetObject.translateX( velX );
targetObject.translateY( velY );
targetObject.translateZ( velZ );
};
```

The `rotationVector`

is probably of most interest to you, so here's what it's doing:

It's using a `THREE.Vector3`

to describe the rotation, the `rotationVector`

variable in this example.

Each component of the `rotationVector`

(`x`

, `y`

, `z`

) is relative to pitch, yaw, and roll respectively.

Set a quaternion's `x`

, `y`

, and `z`

values to the of the rotation vector, making sure the `w`

component is always `1`

(to learn what the `w`

component does, see here, it's a great answer.

Normalizing this quaternion will get us a quaternion of length `1`

, which is very handy when we come to the next step...

`targetObject`

in this case is an instance of `THREE.Object3D`

(a `THREE.Mesh`

, which inherits from `THREE.Object3D`

), so it has a quaternion we can play with.

So now, it's just a matter of multiplying your `targetObject`

's quaternion by your shiny new `rotationQuaternion`

.

Since our object is now rotated to where we want, we can move it along it's new axis angles by using translateX/Y/Z.

The important thing to note here is that quaternions don't act like Euler vectors. Rather than adding two quaternions together to get a new angle, you multiply them.

Anyway, I hope that helps you somewhat!