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I am using RegionPlot3D in Mathematica to visualise some inequalities. As the inequalities are homogeneous in the coordinates they are uniquely determined by their intersection with the unit sphere. This gives some two-dimensional regions on the surface of the sphere which I would like to plot. My question is how?

If requested I would be more than happy to provide some Mathematica code; although I believe that the answer should be independent on the details of the regions I'm trying to plot.

Thanks in advance!

Update: In case anyone is interested, I have recently finished a paper in which I used Sasha's answer below in order to make some plots. The paper is Symmetric M-theory backgrounds and was arXived last week. It contains plots such as this one:

F-moduli space for a symmetric M-theory background

Thanks again!

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1  
I would prefer to see code. –  Mr.Wizard Apr 26 '11 at 10:39
    
Hi José. Welcome to stackoverflow, it's nice to see you over here (and thanks for all of the nice physics notes). –  Simon Apr 26 '11 at 11:45
    
Many thanks, Simon! I'm impressed by the speed this question was answered. It's almost as fast as in MathOverflow :) –  José Figueroa-O'Farrill Apr 26 '11 at 12:07
    
@Jose Welcome to stackoverflow. Please remember to accept one of the answers that solved your problem. The faq has some useful information. –  Sasha Apr 26 '11 at 12:43
    
Dear Sasha, Thanks. I am quite familiar with the software from my involvement in MathOverflow. I tend to wait a little to accept an answer to ensure I accept the best one. I have just been playing with the different answers and I like yours the best, hence I've accepted that. Cheers, José –  José Figueroa-O'Farrill Apr 26 '11 at 12:46

4 Answers 4

up vote 13 down vote accepted

Please look into RegionFunction. You can use your inequalities verbatim in it inside ParametricPlot3D.

Show[{ParametricPlot3D[{Sin[th] Cos[ph], Sin[th] Sin[ph], 
    Cos[th]}, {th, 0, Pi}, {ph, 0, 2 Pi}, 
   RegionFunction -> 
    Function[{x, y, z}, And[x^3 < x y z + z^3, y^2 z < y^3 + x z^2]], 
   PlotRange -> {-1, 1}, PlotStyle -> Red], 
  Graphics3D[{Opacity[0.2], Sphere[]}]}]

enter image description here

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+1 That's probably the smartest way to go about it... –  Simon Apr 26 '11 at 12:02
    
Very beautiful solution! Many thanks. –  José Figueroa-O'Farrill Apr 26 '11 at 12:05
    
+1 The sphere transparency and mesh really help visualize the region. –  David Carraher Apr 26 '11 at 12:13
    
Nice solution, and it works on Mathematica 7. –  Mr.Wizard Apr 26 '11 at 19:21

Here's the simplest idea I could come up with (thanks to belisarius for some of the code).

  • Project the inequalities onto the sphere using spherical coordinates (with θ=q, φ=f).
  • Plot these as a flat region plot.
  • Then plot this as a texture the sphere.

Here's a couple of homogeneous inequalities of order 3

ineq = {x^3 < x y^2, y^2 z > x z^2};

coords = {x -> r Sin[q] Cos[f], y -> r Sin[q] Sin[f], z -> r Cos[q]}/.r -> 1

region = RegionPlot[ineq /. coords, {q, 0, Pi}, {f, 0, 2 Pi}, 
  Frame -> None, ImagePadding -> 0, PlotRangePadding -> 0, ImageMargins -> 0]

flat region

ParametricPlot3D[coords[[All, 2]], {q, 0, Pi}, {f, 0, 2 Pi}, 
 Mesh -> None, TextureCoordinateFunction -> ({#4, 1 - #5} &), 
 PlotStyle -> Texture[Show[region, ImageSize -> 1000]]]

animation

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Thanks. I had thought of projecting to the plane and using RegionPlot but had no idea how to map it back to the sphere. I had no idea about Texture and from the name I would never have guessed that this is what I was looking for! –  José Figueroa-O'Farrill Apr 26 '11 at 12:04
1  
+1 for use of Texture. –  Sasha Apr 26 '11 at 12:05
    
+1 for remembering to turn off the frame and plot range and image padding. –  Brett Champion Apr 26 '11 at 15:51
    
You're welcome :) –  belisarius Apr 26 '11 at 16:08

Simon beat me to the punch but here's a similar idea, based on lower level graphics. I deal with linear, homogeneous inequalities of the form Ax>0.

A = RandomReal[{0, 1}, {8, 3}];
eqs = And @@ Thread[
    A.{Sin[phi] Cos[th], Sin[phi] Sin[th], Cos[phi]} >
        Table[0, {Length[A]}]];
twoDPic = RegionPlot[eqs,
    {phi, 0, Pi}, {th, 0, 2 Pi}];
pts2D = twoDPic[[1, 1]];
spherePt[{phi_, th_}] := {Sin[phi] Cos[th], Sin[phi] Sin[th], 
    Cos[phi]};
rpSphere = Graphics3D[GraphicsComplex[spherePt /@ pts2D,
   twoDPic[[1, 2]]]]

Let's compare it against a RegionPlot3D.

rp3D = RegionPlot3D[And @@ Thread[A.{x, y, z} >
      Table[0, {Length[A]}]],
 {x, -2, 2}, {y, -2, 2}, {z, -2, 2},
   PlotStyle -> Opacity[0.2]];
Show[{rp3D, rpSphere}, PlotRange -> 1.4]
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SphericalPlot3D[0.6, {\[Phi], 0, \[Pi]}, {\[Theta], 0, 2 \[Pi]}, 
 RegionFunction -> 
  Function[{x, y, z}, 
   PolyhedronData["Cube", "RegionFunction"][x, y, z]], Mesh -> False, 
 PlotStyle -> {Orange, Opacity[0.9]}]
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