# Mathematica RegionPlot on the surface of the unit sphere?

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.

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:

Thanks again!

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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

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[]}]}]
``````

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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]
``````

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

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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 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}];
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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