Solved


I'm making a 3D portal system in my engine (like Portal game). Each of the portals has its own orientation saved in a quaternion. To render the virtual scene in one of the portals I need to calculate the difference between the two quaternions, and the result use to rotate the virtual scene.

When creating the first portal on the left wall, and second one on the right wall, the rotation from one to another will take place in only one axis, but for example when the first portal will be created on the floor, and the second one on the right wall, the rotation from one to another could be in two axis, and that's the problem, because the rotation goes wrong.

I think the problem exists because the orientation for example X axis and Z axis are stored together in one quaternion and I need it separately to manualy multiply X * Z (or Z * X), but how to do it with only one quaternion, (the difference quaternion)? Or is there other way to correct rotate the scene?

EDIT:

Here on this picture are two portals P1 and P2, the arrows show how are they rotated. As I am looking into P1 I will see what sees P2. To find the rotation which I need to rotate the main scene to be like the virtual scene in this picture I'm doing following:

  1. Getting difference from quaternion P2 to quaternion P1
  2. Rotating result by 180 degrees in Y axis (portal's UP)
  3. Using the result to rotate the virtual scene

This method above works only when the difference takes place in only one axis. When one portal will be on the floor, or on te ceiling, this will not work because the difference quaternion is build in more than one axis. As suggested I tried to multiply P1's quaternion to P2's quaternion, and inversely but this isn't working.

enter image description here

EDIT 2:

To find the difference from P2 to P1 I'm doing following:

Quat q1 = P1->getOrientation();
Quat q2 = P2->getOrientation();

Quat diff = Quat::diff(q2, q1);  // q2 * diff = q1 //

Here's the Quat::diff function:

GE::Quat GE::Quat::diff(const Quat &a, const Quat &b)
{
    Quat inv = a;
    inv.inverse();
    return inv * b;
}

Inverse:

void GE::Quat::inverse()
{
    Quat q = (*this);
    q.conjugate();
    (*this) = q / Quat::dot((*this), (*this));
}

Conjugate:

void GE::Quat::conjugate()
{
    Quat q;
    q.x = -this->x;
    q.y = -this->y;
    q.z = -this->z;
    q.w = this->w;

    (*this) = q;
}

Dot product:

float GE::Quat::dot(const Quat &q1, const Quat &q2)
{
    return q1.x*q2.x + q1.y*q2.y + q1.z*q2.z + q1.w*q2.w;
}

Operator*:

const GE::Quat GE::Quat::operator* ( const Quat &q) const
{
    Quat qu;
    qu.x = this->w*q.x + this->x*q.w + this->y*q.z - this->z*q.y;
    qu.y = this->w*q.y + this->y*q.w + this->z*q.x - this->x*q.z;
    qu.z = this->w*q.z + this->z*q.w + this->x*q.y - this->y*q.x;
    qu.w = this->w*q.w - this->x*q.x - this->y*q.y - this->z*q.z;
    return qu;
}

Operator/:

const GE::Quat GE::Quat::operator/ (float s) const
{
    Quat q = (*this);
    return Quat(q.x / s, q.y / s, q.z / s, q.w / s);
}

All this stuff works, because I have tested it with GLM library

  • 1
    How are you computing the difference between P2 and P1's quaternions? To find the quaternion q' which will transform q1 into q2, you have to find the inverse of q1, q1^'1 and left-multiply by q2. q' = q2*q1^-1 Refer to Refer to stackoverflow.com/questions/1755631/… – AndyG Mar 3 '14 at 23:33
  • I'm doing it like you say. I have edited my question to show the whole process to find the difference. – Tom Mar 4 '14 at 11:45

If you want to find a quaternion diff such that diff * q1 == q2, then you need to use the multiplicative inverse:

diff * q1 = q2  --->  diff = q2 * inverse(q1)

where:  inverse(q1) = conjugate(q1) / abs(q1)

and:  conjugate( quaternion(re, i, j, k) ) = quaternion(re, -i, -j, -k)

If your quaternions are rotation quaternions, they should all be unit quaternions. This makes finding the inverse easy: since abs(q1) = 1, your inverse(q1) = conjugate(q1) can be found by just negating the i, j, and k components.


However, for the kind of scene-based geometric configuration you describe, you probably don't actually want to do the above, because you also need to compute the translation correctly.

The most straightforward way to do everything correctly is to convert your quaternions into 4x4 rotation matrices, and multiply them in the appropriate order with 4x4 translation matrices, as described in most introductory computer graphics texts.

It is certainly possible to compose Euclidean transformations by hand, keeping your rotations in quaternion form while applying the quaternions incrementally to a separate translation vector. However, this method tends to be technically obscure and prone to coding error: there are good reasons why the 4x4 matrix form is conventional, and one of the big ones is that it appears to be easier to get it right that way.

  • 1
    +1. Quaternions are a double map of SO(3). In particular, q and -q represent the same rotation. This means there's an even easier way to compute q1*conjugate(q2): Negate the real part of q2 rather than the imaginary parts, and then multiply. – David Hammen Mar 4 '14 at 10:43
  • @comingstorm To translate I'm converting the difference quaterinon to rotation matrix and multiply it by rotation matrix by 180 degree in Y axis, and then I'm negating the P2 vector position, next transforming this vector by the rotation matrix, and then the resulting position adding to P1 position. And this is my position where to start drawing the virtual scene. If I change all quaternions to rotation matrices and use only matrices in calculation, will be there any difference? – Tom Mar 4 '14 at 12:03
up vote 3 down vote accepted

I solved my problem. As it turned out I don't need any difference between two rotations. Just multiply one rotation by rotation in 180 degrees, and then multiply by inverse of second rotation that way (using matrices):

Matrix m1 = p1->getOrientation().toMatrix();
Matrix m2 = p2->getOrientation().toMatrix();
Matrix model = m1 * Matrix::rotation(180, Vector3(0,1,0)) * Matrix::inverse(m2);

and translation calculating this way:

Vector3 position = -p2->getPosition();
position = model * position + p1->getPosition();
model = Matrix::translation(position) * model;
  • 1
    Glad you solved your issue, Tom. Thanks for posting it here so that others may see it in the future. – AndyG Mar 4 '14 at 17:01

No, you have to multiply two quaternions together to get the final quaternion you desire.

Let's say that your first rotation is q1 and the second is q2. You want to apply them in that order.

The resulting quaternion will be q2 * q1, which will represent your composite rotation (recall that quaternions use left-hand multiplication, so q2 is being applied to q1 by multiplying from the left)

Reference

For a brief tutorial on computing a single quaternion, refer to my previous stack overflow answer

Edit:

To clarify, you'd face a similar problem with rotation matrices and Euler angles. You define your transformations about X, Y, and Z, and then multiply them together to get the resulting transformation matrix (wiki). You have the same issue here. Rotation matrices and Quaternions are equivalent in most ways for representing rotations. Quaternions are preferred mostly because they're a bit easier to represent (and easier for addressing gimbal lock)

  • Thanks for Your answer. I tried to multiply q1 and q2 but this is not working. I have edited my question to be more clearer – Tom Mar 3 '14 at 22:40

Quaternions work the following way: the local frame of reference is represented as the imaginary quaternion directions i,j,k. For instance, for an observer standing in the portal door 1 and looking in the direction of the arrow, direction i may represent the direction of the arrow, j is up and k=ij points to the right of the observer. In global coordinates represented by the quaternion q1, the axes in 3D coordinates are

q1*(i,j,k)*q1^-1=q1*(i,j,k)*q1',

where q' is the conjugate, and for unit quaternions, the conjugate is the inverse.

Now the task is to find a unit quaternion q so that directions q*(i,j,k)*q' in local frame 1 expressed in global coordinates coincide with the rotated directions of frame 2 in global coordinates. From the sketch that means forwards becomes backwards and left becomes right, that is

q1*q*(i,j,k)*q'*q1'=q2*(-i,j,-k)*q2'
                   =q2*j*(i,j,k)*j'*q2'

which is readily achieved by equating

q1*q=q2*j or q=q1'*q2*j.

But details may be different, mainly that another axis may represent the direction "up" instead of j.


If the global system of the sketch is from the bottom, so that global-i points forward in the vertical direction, global-j up and global-k to the right, then local1-(i,j,k) is global-(-i,j,-k), giving

q1=j. 

local2-(i,j,k) is global-(-k,j,i) which can be realized by

q2=sqrt(0.5)*(1+j), 

since

(1+j)*i*(1-j)=i*(1-j)^2=-2*i*j=-2*k and 
(1+j)*k*(1-j)=(1+j)^2*k= 2*j*k= 2*i

Comparing this to the actual values in your implementation will indicate how the assignment of axes and quaternion directions has to be changed.

Check https://www.emis.de/proceedings/Varna/vol1/GEOM09.pdf

Imagine to get dQ from Q1 to Q2, I'll explain why dQ = Q1*·Q2, instead of Q2·Q1*

This rotates the frame, instead of an object. For any vector v in R3, the rotation action of operator L(v) = Q*·v·Q

It's not Q·v·Q*, which is object rotation action.

If you rotates Q1 and then Q1* and then Q2, you can write (Q1·Q1*·Q2)*·v·(Q1·Q1*·Q2) = (Q1*·Q2)*·Q1*·v·Q1·(Q1*·Q2) = dQ*·Q1*·v·Q1·dQ

So dQ = Q1*·Q2

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