*Disclaimer: I'm pretty new to Quaternions myself but have done some work "near" them. The below is the result of my limited knowledge plus a few Google searches. It sure looks like it ought to do the trick.*

So it sounds like the problem you're trying to solve can be stated as follows:

- Given two quaternions (which represent the 3D orientation of the upper and lower leg, respectively)...
- ...calculate the 3D angular difference between the two quaternions...
- ... and represent that angular difference as Euler angles

To get the 3D angular difference, which itself is a quaternion, you just multiply one quaternion by the conjugate of the other (reference).

Then you need to convert from a quaternion to Euler angles (rotation about X, Y, Z). From what I can tell you'll need to do that The Old Fashioned Way, using the formulas from Wikipedia.

Sample code, using the pyquaternion library:

```
import pyquaternion as pyq
import math
# Create a hypothetical orientation of the upper leg and lower leg
# We use the (axis, degrees) notation because it's the most intuitive here
# Upper leg perfectly vertical with a slight rotation
q_upper = pyq.Quaternion(axis=[0.0, 0.0, -1.0], degrees=-5)
# Lower leg a little off-vertical, with a rotation in the other direction.
q_lower = pyq.Quaternion(axis=[0.1, -0.2, -0.975], degrees=10)
# Get the 3D difference between these two orientations
qd = q_upper.conjugate * q_lower
# Calculate Euler angles from this difference quaternion
phi = math.atan2( 2 * (qd.w * qd.x + qd.y * qd.z), 1 - 2 * (qd.x**2 + qd.y**2) )
theta = math.asin ( 2 * (qd.w * qd.y - qd.z * qd.x) )
psi = math.atan2( 2 * (qd.w * qd.z + qd.x * qd.y), 1 - 2 * (qd.y**2 + qd.z**2) )
# Result:
# phi = 1.16 degrees
# theta = -1.90 degrees
# psi = -14.77 degrees
```

Caveats:

- I haven't hand-verified the correctness of this but it sure looks like it ought to be right.
- You will of course want to be sure you verify the actual orientation and sign of each of the angles (phi, theta, psi) versus what you expect them to be.
- In the Wikipedia article (in their C sample code) they add a little correction to the
`asin`

call for calculating theta. I'm not sure if that's needed. But if theta truly is adduction, I'm guessing you won't need to worry about angles above 90 degrees anyway ;-)