Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

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:

enter image description here

share|improve this question

3 Answers 3

up vote 5 down vote accepted

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]}]

Ternary Cantor set

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]

enter image description here


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]}]

more dust

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:

enter image description here

share|improve this answer
    
+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

enter image description here

share|improve this answer
    
+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.

share|improve this answer
    
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

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.