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I've a rotation represented as a quaternion and am trying to constrain the pitch, yaw, & roll axes. I tried doing so thusly:

public struct Orientation
{
    public Vector3 up, forward;

    public Orientation(Vector3 up, Vector3 forward)
    {
        this.up = up;
        this.forward = forward;
    }
}

public static Orientation[] orientations = new Orientation[3]
{
    new Orientation(Vector3.right, Vector3.up),
    new Orientation(Vector3.up, Vector3.forward),
    new Orientation(Vector3.forward, Vector3.right)
};

public enum Axis
{
    Pitch,
    Yaw,
    Roll
};

private Vector3 ConstrainAxis(Vector3 vector, Axis axis, float from, float to)
{
    Orientation orientation = orientations[(int)axis];

    float theta = (to - from) * 0.5F;

    Vector3 cons = Quaternion.AngleAxis(from + theta, orientation.up) * orientation.forward;
    Vector3 proj = Vector3.ProjectOnPlane(vector, orientation.up);

    return ConstrainVector(cons.normalized, proj.normalized, theta);
}

private Vector3 ConstrainVector(Vector3 from, Vector3 to, float angle)
{
    float theta = Mathf.Abs(angle / Vector3.Angle(from, to));

    if(theta < 1.0F)
    {
        return Vector3.Slerp(from, to, theta);
    }

    return to;
}

Which turned out to be nothing more than an over-complicated way of constraining the individual components of an euler angle representation, of which both are subject to a strange jittering issue (gimbal lock related?).

What is the best approach to constraining these axes?

  • Constraining Euler Angels sounds like incorrect task. It is not fit to psysical motion , and probably is used to constrain only 2 axes. Is it possible that your task represent constraints of swing twist constraint of joint? – minorlogic Sep 28 '15 at 9:44
  • Indeed it does. I have an IK system where I need to constrain the joints. – Tannz0rz Sep 28 '15 at 14:28
  • 1
    Than you can decompose rotation into twist swing ? and apply constraints like in this tip alinenormoyle.com/weblog/?p=726 – minorlogic Sep 28 '15 at 14:55
  • That's very nice, but I can't say I understand how I would go about applying a constraint to a quaternion in this fashion. Is it as simple as constraining the real part w? – Tannz0rz Sep 28 '15 at 16:05
  • 1
    you can constraint quat with angle axis or directly constrain the magnitude of quat "vector" part. (don't forget , it is sin(0.5 * angle), and recalculate W with sqrt(1- vector_part.magnitude())) – minorlogic Sep 29 '15 at 8:01
2

For joint constraints it is common practice to use "swing twist" parametrization. To represent current rotation as "swing twist" for quaternions, theare are good decomposition http://www.alinenormoyle.com/weblog/?p=726

And constraint for "swing" and "twist" can be done with quaternions.

if we want to constrain swing to +-30 degrees , pseudocode looks like

Quaternion swing;
const double maxMagnitude = sin( 0.5 * toRad(30) );
const double maxMagnitudeW = sqrt(1.0 - maxMagnitude*maxMagnitude );
if(swing.vec().normSqr() > maxMagnitude*maxMagnitude)
{
  swing.vec() = swing.vec().normalized() * maxMagnitude;
  swing.w() = maxMagnitudeW;
}
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Adding to minorlogic's answer: it is important to save the the sign of targetQuat's W component. Here is a three.js implementation of twist constraint. Also seems there are some singularities I have not checked for: http://www.allenchou.net/2018/05/game-math-swing-twist-interpolation-sterp/

const HEAD_YAW_MAX = 40
const MAX_MAGNITUDE = Math.sin(0.5 * THREE.Math.degToRad(HEAD_YAW_MAX));
const MAX_MAGNITUDE_W = Math.sqrt(1.0 - MAX_MAGNITUDE * MAX_MAGNITUDE);
const MAX_MAG_POW_2 = MAX_MAGNITUDE * MAX_MAGNITUDE;

in update function

const qT = this.headBone.quaternion;
v1.set(qT.x, qT.y, qT.z); //todo check singularity: rotation by 180
v1.projectOnVector(this.headBone.up); //up is direction around twist
// v1.set(0, qT.y, 0); //project on y axis
q1.set(v1.x, v1.y, v1.z, qT.w); //twist
q1.normalize();
q3.copy(q1).conjugate();
q2.multiplyQuaternions(qT, q3); //swing
q2.normalize();
v1.set(q1.x, q1.y, q1.z);
if (v1.lengthSq() > MAX_MAG_POW_2) {
   v1.setLength(MAX_MAGNITUDE);
   const sign = qT.w < 0 ? -1 : 1;
   q1.set(v1.x, v1.y, v1.z, sign * MAX_MAGNITUDE_W);
   this.headBone.quaternion.multiplyQuaternions(q2, q1); //swing * twist
}

The source for the swing twist parameterization algorithm: Component of a quaternion rotation around an axis

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