# How can I plot a function defined on the unit simplex in Mathematica?

I am trying to plot a function in Mathematica that is defined over the unit simplex. To take a random example, suppose I want to plot sin(x1*x2*x3) over all x1, x2, x3 such that x1, x2, x3 >= 0 and x1 + x2 + x3 = 1. Is there a neat way of doing so, other than the obvious way of writing something like

``````Plot3D[If[x+y<=1,Sin[x y(1-x-y)]],{x,0,1},{y,0,1}]
``````

?

What I want, ideally, is a way of plotting only over the simplex. I found the website http://octavia.zoology.washington.edu/Mathematica/ which has an old package, but it doesn't work on my up-to-date version of Mathematica.

-

Try:

``````Plot3D[Sin[x y (1 - x - y)], {x, 0, 1}, {y, 0, 1 - x}]
``````

But you can also use `Piecewise` and `RegionFunction`:

``````Plot3D[Piecewise[{{Sin[x y (1 - x - y)],
x >= 0 && y >= 0 && x + y <= 1}}], {x, 0, 1}, {y, 0, 1},
RegionFunction -> Function[{x, y}, x + y <= 1]]
``````
-
these give the same results as the code I posted in my original question. – unknowngoogle Feb 26 '11 at 0:18

If you want to get symmetric looking plots like in that package you linked, you need to figure out rotation matrix that puts the simplex into x/y plane. You can use this function below. It's kind of long because I left in the calculations to figure out simplex centering. Ironically, transformation for 4d simplex plot is much simpler. Modify `e` variable to get different margin

``````simplexPlot[func_, plotFunc_] :=
Module[{A, B, p2r, r2p, p1, p2, p3, e, x1, x2, w, h, marg, y1, y2,
valid},
A = Sqrt[2/3] {Cos[#], Sin[#], Sqrt[1/2]} & /@
Table[Pi/2 + 2 Pi/3 + 2 k Pi/3, {k, 0, 2}] // Transpose;
B = Inverse[A];

(* map 3d probability vector into 2d vector *)
p2r[{x_, y_, z_}] := Most[A.{x, y, z}];

(* map 2d vector in 3d probability vector *)
r2p[{u_, v_}] := B.{u, v, Sqrt[1/3]};

(* Bounds to center the simplex *)
{p1, p2, p3} = Transpose[A];

(* extra padding to use *)
e = 1/20;

x1 = First[p1] - e/2;
x2 = First[p2] + e/2;
w = x2 - x1;
h = p3[[2]] - p2[[2]];
marg = (w - h + e)/2;
y1 = p2[[2]] - marg;
y2 = p3[[2]] + marg;

valid =
Function[{x, y}, Min[r2p[{x, y}]] >= 0 && Max[r2p[{x, y}]] <= 1];
plotFunc[func @@ r2p[{x, y}], {x, x1, x2}, {y, y1, y2},
RegionFunction -> valid]
]
``````

Here's how to use it

``````simplexPlot[Sin[#1 #2 #3] &, Plot3D]
``````

``````simplexPlot[Sin[#1 #2 #3] &, DensityPlot]
``````

If you want to see domain in the original coordinate system, you could rotate the plot back to the simplex

``````t = AffineTransform[{{{-(1/Sqrt[2]), -(1/Sqrt[6]), 1/Sqrt[3]}, {1/
Sqrt[2], -(1/Sqrt[6]), 1/Sqrt[3]}, {0, Sqrt[2/3], 1/Sqrt[
3]}}, {1/3, 1/3, 1/3}}];
graphics = simplexPlot[5 Sin[#1 #2 #3] &, Plot3D];
shape = Cases[graphics, _GraphicsComplex];
Graphics3D[{Opacity[.5], GeometricTransformation[shape, t]},
Axes -> True]
``````

Here's another simplex plot, using traditional 3d axes from here and `MeshFunctions->{#3&}`, complete code here

-
Thanks, @Yaroslav. What I was really hoping for, though, was that the axes would lie along the sides of the simplex, so that we could really think of the plot as being on the simplex itself. An acceptable alternative, I suppose, would be to remove the border and to label to corners x1=1, x2=1, and x3=1 (the remaining two variables implicitly being zero when the third equals one). – unknowngoogle Feb 24 '11 at 17:05
@unknowngoogle updated – Yaroslav Bulatov Feb 24 '11 at 20:55
Thanks again @Yaroslav. What I was imagining was a plot like your first figure above, but minus the enclosing box, and with the corners labelled appropriately. But now you've given me all these tips I should probably try to work it out myself rather than freeriding on you! – unknowngoogle Feb 25 '11 at 4:28
Enclosing box is controlled by `Frame` option, you can make corner labels with `labels=Graphics[Text[#, p2r@#] & /@ IdentityMatrix@3];` Combine original plot and labels using `Show`. – Yaroslav Bulatov Feb 26 '11 at 6:30