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# how to generate a plot of planar Cantor set in mathematica

I am wondering if anyone can help me to plot the Cantor dust on the plane in Mathematica. This is linked to the Cantor set.

Thanks a lot.

EDIT

I actually wanted to have something like this:

-

Here's a naive and probably not very optimized way of reproducing the graphics for the ternary Cantor set construction:

``````cantorRule = Line[{{a_, n_}, {b_, n_}}] :>
With[{d = b - a, np = n - .1},
{Line[{{a, np}, {a + d/3, np}}], Line[{{b - d/3, np}, {b, np}}]}]

Graphics[{CapForm["Butt"], Thickness[.05],
Flatten@NestList[#/.cantorRule&, Line[{{0., 0}, {1., 0}}], 6]}]
``````

To make Cantor dust using the same replacement rules, we take the result at a particular level, e.g. 4:

``````dust4=Flatten@Nest[#/.cantorRule&,Line[{{0.,0},{1.,0}}],4]/.Line[{{a_,_},{b_,_}}]:>{a,b}
``````

and take tuples of it

``````dust4 = Transpose /@ Tuples[dust4, 2];
``````

Then we just plot the rectangles

``````Graphics[Rectangle @@@ dust4]
``````

## Edit: Cantor dust + squares

Changed specs -> New, but similar, solution (still not optimized).
Set n to be a positive integer and choice any subset of 1,...,n then

``````n = 3; choice = {1, 3};
CanDChoice = c:CanD[__]/;Length[c]===n :> CanD[c[[choice]]];
splitRange = {a_, b_} :> With[{d = (b - a + 0.)/n},
CanD@@NestList[# + d &, {a, a + d}, n - 1]];

cantLevToRect[lev_]:=Rectangle@@@(Transpose/@Tuples[{lev}/.CanD->Sequence,2])

dust = NestList[# /. CanDChoice /. splitRange &, {0, 1}, 4] // Rest;

Graphics[{FaceForm[LightGray], EdgeForm[Black],
Table[cantLevToRect[lev], {lev, Most@dust}],
FaceForm[Black], cantLevToRect[Last@dust /. CanDChoice]}]
``````

Here's the graphics for

``````n = 7; choice = {1, 2, 4, 6, 7};
dust = NestList[# /. CanDChoice /. splitRange &, {0, 1}, 2] // Rest;
``````

and everything else the same:

-
+1 and thank you. I actually wanted to have a plot as the one I attached here. Could you please help with that? It seems more difficult to get a plot like that. – Qiang Li Jul 9 '11 at 1:21
@QiangLi: grrr... ok. See edit. – Simon Jul 9 '11 at 4:58
thanks a lot. I need some explanation here. First of all, I think `np = n - .1` should be `np = n - 1`, shouldn't it? Just puzzled at why the code still produced the correct results? Also how about this line `cantorRule = {CanD[x_,y_,z_]:>(CanD[x,z]/.cantorRule), {a_,b_}:>With[{d=(b-a)/3.},CanD@@NestList[#+d&,{a,a+d},2]]};`? I cannot fully understand... – Qiang Li Jul 11 '11 at 2:37
@QiangLi: The `np=n-.1` was just to get the y-axis spacing right in the first image. Those terms are thrown away in the 2nd image - and a different rule is used to generate the 3rd image. – Simon Jul 11 '11 at 3:43
@QiangLi: As for the final `cantorRule`, it does two things. The 2nd term takes a pair of x-coordinates and returns a sequence that divides it into 3 equal parts. These are used for drawing the empty squares. The 1st rule then takes these three parts and throws away the middle term - this is what stops the whole thing being filled evenly with squares. Note that in the `Graphics` command I have to manually throw away the middle term when drawing the final, filled squares. – Simon Jul 11 '11 at 3:47

Once can use the following approach. Define cantor function:

``````cantorF[r:(0|1)] = r;
cantorF[r_Rational /; 0 < r < 1] :=
Module[{digs, scale}, {digs, scale} = RealDigits[r, 3];
If[! FreeQ[digs, 1],
digs = Append[TakeWhile[Most[digs]~Join~Last[digs], # != 1 &], 1];];
FromDigits[{digs, scale}, 2]]
``````

Then form the dust by computing differences of `F[n/3^k]-F[(n+1/2)/3^k]`:

``````With[{k = 4},
Outer[Times, #, #] &[
Table[(cantorF[(n + 1/2)/3^k] - cantorF[(n)/3^k]), {n, 0,
3^k - 1}]]] // ArrayPlot
``````

-
+1 More sophisticated than my approach! – Simon Jul 9 '11 at 5:05

I like recursive functions, so

``````cantor[size_, n_][pt_] :=
With[{s = size/3, ct = cantor[size/3, n - 1]},
{ct[pt], ct[pt + {2 s, 0}], ct[pt + {0, 2 s}], ct[pt + {2 s, 2 s}]}
]

cantor[size_, 0][pt_] := Rectangle[pt, pt + {size, size}]

drawCantor[n_] := Graphics[cantor[1, n][{0, 0}]]

drawCantor[5]
``````

Explanation: `size` is the edge length of the square the set fits into. `pt` is the `{x,y}` coordinates of it lower left corner.

-
Nice and clean +1! It's also fairly simple to modify to take arbitrary division patterns (animation generated from code). – Simon Jul 11 '11 at 5:39