# Plot DelaunayTriangulation in Mathematica

Considering the following example (from Sjoerd Solution on plotting a ConvexHull)

``````Needs["ComputationalGeometry`"]
pts = RandomReal[{0, 10}, {60, 2}];
dtpts=DelaunayTriangulation[pts]
``````

I would now like to plot the DelaunayTriangulation for a set of point but can`t figure out the Plot syntax using Graphics.

Thoughts ?

-

``````Graphics[
GraphicsComplex[
pts,
{
Function[{startPt, finishPts},Line[{startPt, #}] & /@ finishPts] @@@ dtpts,
Red, Point@Range[Length@pts]
}
]
]
``````

And if you need real polygons:

``````Graphics[
GraphicsComplex[
pts,
{EdgeForm[Black],
Function[{startPt, finishPts},
{FaceForm[RGBColor[RandomReal[], RandomReal[], RandomReal[]]],
Polygon[{startPt, ##}]} & @@@
Transpose[{Drop[finishPts, 1],
Drop[RotateRight@finishPts, 1]
}
]
] @@@ dtpts,
Red, Point@Range[Length@pts]
}
]
]
``````

-
@Sjoerd, thank you again ! I edited my question to describe dtpts. – 500 Jun 24 '11 at 14:58
New interpretation of the output. This is better – Sjoerd C. de Vries Jun 24 '11 at 15:22
@Sjoerd, thank you ! I love the colors. – 500 Jun 24 '11 at 16:02
Well, it still isn't perfect. The way they are generated, all polygons appear multiple times in the triangulation results. But that's a question of sorting and using Union. – Sjoerd C. de Vries Jun 24 '11 at 16:23
@Sjoerd, would you know how to count the number of edges ? – 500 Jun 24 '11 at 16:43

I like Sjoerd's use of `GraphicsComplex`, but I don't see the need for the baroque code in the middle.

This appears to work just fine:

``````Needs["ComputationalGeometry`"]
pts = RandomReal[{0, 10}, {60, 2}];
dtpts = DelaunayTriangulation[pts];
``````

## Lines

``````Graphics[GraphicsComplex[
pts,
{Line /@ Thread /@ dtpts, Red, Point@Range@Length@pts}
]]
``````

## Polygons

``````Graphics[GraphicsComplex[
pts,
{
EdgeForm[Black],
( {FaceForm[RGBColor @@ RandomReal[1, 3]], Polygon@#} & /@
Append @@@ Thread@{Partition[#2, 2, 1], #} & ) @@@ dtpts,
Red,
Point@Range[Length@pts]
}
]]
``````

-
Mr Wizard, Thank You ! – 500 Aug 24 '11 at 14:51

Method one, using polygons like Sjoerd, but without the problem caused by points on the convex hull:

``````Graphics[{FaceForm[], EdgeForm[Black],
Polygon[pts[[#]] & /@
DeleteCases[dtpts, {i_, _} /; MemberQ[ConvexHull[pts], i]][[All,
2]]], Red, Point[pts]}]
``````

Method two, using lines connecting the adjacent points:

``````edges[pts_, {a_, l_List}] := {pts[[a]], #} & /@ pts[[l]]
Graphics[{Line[edges[pts, #]] & /@ dtpts, Red, Point[pts]}]
``````

Both of these methods result in duplicated primitives (three polygons or two lines, from using each point as a starting point.)

We can modify the data slightly and use built in visualization functions:

``````Graphics[{FaceForm[], EdgeForm[Black],
Cases[Normal[
ListDensityPlot[{##, 0.} & @@@ pts, Mesh -> All]], _Polygon,
Infinity], Red, Point[pts]}, ImageSize -> 175]
``````

-
I already changed my solution 15 minutes ago. I have a polygon solution ready for an update too... – Sjoerd C. de Vries Jun 24 '11 at 15:53
Thank you very much ! – 500 Jun 24 '11 at 16:01