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"Chaanakya" <nomail@nomail> wrote:
> clipka <ano### [at] anonymous org> wrote:
> > Am 23.07.2012 22:52, schrieb Chaanakya:
> > > clipka <ano### [at] anonymous org> wrote:
> > >> Am 23.07.2012 21:58, schrieb Chaanakya:
> > >>> "Chaanakya" <nomail@nomail> wrote:
> > >>>> Hey guys! I just had a quick question...
> > >>>>
> > >>>> I was trying to generate the graph of this function (in Cartesian
coordinates):
> > >>>>
> > >>>> -z + 1.00003 = (3x^2 + 3y^2)/(200000)
> > >>>>
> > >>>> However, when I render the following code, nothing shows up except for the
> > >>>> plane:
> > >> ...
> > >>>> isosurface {
> > >>>> function {
> > >>>> -y - ((3*pow(x,2) + 3*pow(z,2))/(200000)) + 1.00003
> > >>>> }
> > >>>> // contained_by { box { -2,2 } }
> > >>>> pigment {
> > >>>> color Red
> > >>>> }
> > >>>> }
> > >> ...
> > >>> Even more strangely, when I use the equally valid function
> > >>>
> > >>> function {
> > >>> y + 3*pow(x,2)/200000 + 3*pow(z,2)/200000 - 1.00003
> > >>> }
> > >>>
> > >>> I get a cube. I think there's something fundamental about isosurfaces that
I'm
> > >>> not understanding? That is, how should I convert the function z =
-3x^2/200000
> > >>> - 3y^2/200000 + 1.00003 into an isosurface?
> > >>
> > >> Do un-comment the "contained_by" line!
> > >>
> > >> At x=0,z=0 you have y = 1.00003, which is outside the default
> > >> contained_by object (box{1,1}), and even at the maximum x and z
> > >> (x=1,z=1) you have y = 1.00000, which just barely touches the box.
> > >>
> > >> I.e. the surface you defined is (for practical purposes) all outside
> > >> default container; so the inside of the default container is either
> > >> completely outside the isosurface (first version) so that you don't see
> > >> anything, or completely inside (second version) so that you simply see
> > >> the container's shape.
> > >
> > > I'm trying to figure out exactly what container I should use - if I use box {
> > > <-1,1,-1>,<1,1.00003,1> } I get nothing (I understand why). If I use box {
> > > <-1,0.9,-1>,<1,1.00003,1> } I get a box. How do I get the elliptic paraboloid
> > > to show up?
> >
> > At the current dimensions, the curvature of the isosurface is simply too
> > small to be noticeable
> >
> > You'll need to use a much larger bounding container (and move back the
> > camera a whole lot) to see anything. Something like
> > contained_by{box{-20000,20000}}.
> >
> > (BTW your elliptic paraboloid seems pretty circular to me.)
>
> I think I figured out another way of doing what I want to do using spheres. I
> will try it out and report back.
I'm essentially trying to get a 0.00003 unit chunk out of the top of the sphere.
I found an example for the hemisphere and I will try to work with that (I kind
of get how to do it, but I can't seem to get the chunk I need experimenting with
the box in the intersection).
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