How to constrain 3D rotations (Euler)

Question

What's the correct/best way of constraining a 3D rotation (using Euler angles and/or quaternions)?

It seems like there's something wrong with my way of doing it. I'm applying the rotations to bones in a skeletal hierarchy for animation, and the bones sometimes visibly "jump" into the wrong orientation, and the individual Euler components are wrapping around to the opposite end of their ranges.

I'm using Euler angles to represent the current orientation, converting to quaternions to do rotations, and clamping each Euler angle axis independently. Here's C++ pseudo-code showing basically what I'm doing:

Euler min = ...;
Euler max = ...;

Quat rotation = ...;
Euler eCurrent = ...;

// do rotation
Quat qCurrent = eCurrent.toQuat();
qCurrent = qCurrent * rotation;
eCurrent = qCurrent.toEuler();

// constrain
for (unsigned int i = 0; i < 3; i++)
    eCurrent[i] = clamp(eCurrent[i], min[i], max[i]);

Answer 1

One problem with Euler angles is that there are multiple ways to represent the same rotation, so you can easily create a sequence of rotations that are smooth, but the angles representing that rotation may jump around. If the angles jump in and out of the constrained range, then you will see effects like you are describing.

Imagine that only the X rotation was involved, and you had constrained the X rotation to be between 0 and 180 degrees. Also imagine that your function that converts the quaternion to Euler angles gave angles from -180 to 180 degrees.

You then have this sequence of rotations:

True rotation    After conversion    After constraint
179              179                 179
180              180                 180
181             -179                 0

You can see that even though the rotation is changing smoothly, the result will suddenly jump from one side to the other because the conversion function forces the result to be represented in a certain range.

When you are converting the quaternion to Euler angles, find the angles that are closest to the previous result. For example:

eCurrent = closestAngles(qCurrent.toEuler(),eCurrent);
eConstrained = clampAngles(eCurrent,min,max);

remember the eCurrent values for next time, and apply the eConstrained rotations to your skeleton.

Answer 2

The problem here is that the constraints you are applying have no relation to the rotation be applied. From a conceptual point of view this is what you are trying to achieve:

• assume a bone is in an unconstrained state.
• apply rotation
• has bone exceeded constraints? If yes, rotate it to where it is not constrained any more

Your code that clamps the Euler rotations is the part where you rotating the bone back. However this code ignores the original bone rotation so you will see odd behavior, such as the snapping you are seeing.

A simple way to work with this is to do this instead:

• assume a bone is in an unconstrained state
• apply rotation
• test if bone exceeded constraints
• if yes, we need to find where the constraint stops movement.
  1. halve the rotation, apply it in reverse
  2. is the bone exceeding constraints? If yes go to 1
  3. If no, halve the rotation, apply it in the forward direction. Goto 2
• keep doing that until you are within some tolerance of your constraining angles

Now this will work, but because your rotation quarternions is being applied on all angles, the rotation will stop when any one of those constraints are net, even if there is freedom some where else.

If instead you apply rotations independently of each other, then you will be able to reliable use your clamping or the above technique to honor constraints, and also rotate as closely to your target as you can. - -