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for a 3d imaging software i am coding:

I need to define an ellipsoid E, which can have any radii, centers and rotations in space alt text

the user interface allows the user to control 3 ellipses, which are "slices" of the ellipsoid (red,green,blue in the image) ,and are parallel (by definition) to the main Cartesian planes (x-y, y-z. x-z)

these 3 ellipses are part of, and define, the whole ellipsoid alt text

each slice can be dragged, resized or rotated in space and each slice is fully defined: it's center's 3d position in space, it's 2 radiuses, it's distance from the axis planes.

each change should, obviously, affect the parameters of the ellipsoid E, and the other 2 derived ellipses.

i need the equation to re-calculate ellipsoid E based on the changes made to a slice

(The preferred type of equation for the ellipsoid should make it easy to derive the X-Y ellipse cuts (variable z))

any ideas? thanx in advance Saar

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I guess you may think again this phrase each change should, obviously, affect the parameters of the ellipsoid E, and the other 2 derived ellipses So ... What is fixed? – Dr. belisarius Nov 25 '10 at 12:47
i didn't understand your comment – Saariko Nov 25 '10 at 19:13
@belisarius the relationship between the 3 ellipses and the ellipsoid is fixed. this equation (=relationship) is what i am trying to figure out! – Saariko Nov 25 '10 at 23:01
The trouble is that although the ellipsoid determines the ellipses, the x-plane ellipse does not uniquely determine the ellipsoid. So if you change the x-plane ellipse, you must pick something else that is to remain constant in order to determine the new ellipsoid uniquely. – Beta Nov 25 '10 at 23:24
@Beta yep. That was the intention of my previous question. – Dr. belisarius Nov 25 '10 at 23:38

I think the key to this problem is to rewrite the initial ellipse equation in matrix form: xTAx, where x = {x,y,z} and A is positive definite. Taking

Ellipsoid matrix.

we can update A via a similarity transform. So that, the updated matrix is then A' = UTAU where U is an orthogonal matrix and UT is its transpose. Then A' is used to update the other views.

Starting with the rotation matrices about the three axes

Rotation Matrices about the three axes.

we can see quite clearly that a rotation about the axes will effect 8 terms in A. Since, A is symmetric this is reduced to only changing 5 out of 6 terms. Scaling/stretching is also very easily done.

We start by assuming that the stretch is along the x-axis (or any appropriate axis), so that S is a diagonal matrix with a diagonal {sqrt( s ), 1, 1}, where s is the amount of stretch applied. Then scaling matrix is rotated into the correct direction of application, i.e. RTheta S RThetaT, where Theta is the angle between the positive x-axis and the stretch direction in a clockwise fashion. Note the reverse order of the rotations here, as RThetaT can be thought of as rotating the coordinates so that S stretches the x-axis and RTheta rotates them back. For example, if the x-y plane is rescaled along x = y by a factor of s, then

scaling matrix

S is applied to A in the same way as the rotations, and, again, it is straightforward to see that all but the zz terms are directly affected by the scaling operation.

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Here you have an example of an intractable situation:

One true allipsoid and an sphere whose intersections with the three coordinate planes are points. In this example, you are not able to decide which quadric you should map.

alt text

alt text

The equations for these surfaces are:

 (-1 + x)^2 + (-1 + y)^2 + (-1 + z)^2 == 1  


1/8 (12 + 3 x^2 + 3 y^2 - 2 y (2 + z) - 2 x (2 + y + z) + z (-4 + 3 z)) == 1

So, as your solutions are not uniquely defined, you can't reconstruct your ellipsoid based on the three intersections. I think other answers to your question do not account for translations.

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@belisarius, forgive me, but I don't see where the problem went from working with three mutually perpendicular planar slices of an ellipsoid to the intersection of the ellipsoid with a sphere. I understand where the idea for the sphere came from, in that the ellipsoid is initially a sphere, but how we get to it intersecting the ellipsoid is not clear. – rcollyer Dec 6 '10 at 21:03
@rcollyer The problem is not the intersection of the sphere and ellipsoid. The problem is that both intersect the three planes in the same points, so based in just the intersections you can't know which of those surfaces you should render in 3D – Dr. belisarius Dec 6 '10 at 21:14
@belisarius, ah, I see. If the intersections are reduced to their limits, i.e. points, then there is no way to establish the actual ellipsoid. I think this problem will occur if any of the intersections become points, or no longer intersect with the ellipsoid. Thanks. – rcollyer Dec 6 '10 at 21:19
@rcollyer Is there a formal prove that if the intersections are not points or nulls then the ellipsoid is unique? – Dr. belisarius Dec 7 '10 at 12:43
@belisarius, I think if some conditions are met, then yes the equation of the ellipsoid can be constructed from the equations of the ellipses. I believe that two of the principle axes of the ellipsoid must lie in the plane where an ellipse is embedded, otherwise the relationship is ambiguous. However, if the ellipsoid is crafted from a known initial condition, like a sphere, then I think the ambiguity can be avoided. But, that requires an answer to my questions posted to the OP, above. – rcollyer Dec 7 '10 at 13:42

If, at a given instance, the 3 Ellipses represent "Cartesian" cuts of E, a single modification of any of (pan, zoom, rotate) of any of them redefines a unique ellipsoid. Luckily there is one mouse (or single recognized Keystroke) or one mind for this matter..

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