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# Generating topological space diagram in Mathematica

I have mathematica code to check whether a collection of sets satisfies the definition of a topology, I would now like to programmatically generate diagrams like these:

How can this be done?

-

I'm not familiar with your problem but to create diagrams from primitives, that look kind of like the ones you have pasted, you can do this:

``````base = {Circle[{-0.4, 0.4}, 0.1], Disk[{0, .125}, 0.05],
Text[Style["1", 24], {0, -0.1}],
Disk[{0.5, .125}, 0.05], Text[Style["2", 24], {0.5, -0.1}],
Disk[{1., .125}, 0.05], Text[Style["3", 24], {1., -0.1}],
Circle[{.5, 0}, {.9, .5}]};

Graphics[{base}, ImageSize -> 220]
``````

From here just add elipses to the base case:

``````Graphics[{base, Circle[{0, 0}, {.15, .3}]}, ImageSize -> 220]
``````

``````Graphics[{base, Circle[{0, 0}, {.15, .3}],
Circle[{0.5, 0}, {.15, .3}], Circle[{0.25, 0}, {.58, .38}]},
ImageSize -> 220]
``````

``````Graphics[{base, Circle[{0.5, 0}, {.15, .3}],
Circle[{0.25, 0}, {.58, .38}], Circle[{0.75, 0}, {.58, .38}]},
ImageSize -> 220]
``````

``````Graphics[{base, Circle[{0.5, 0}, {.15, .3}],
Circle[{1, 0}, {.15, .3}], Red, AbsoluteThickness[6],
Line[{{-0.4, -0.5}, {1.4, 0.55}}],
Line[{{-0.4, 0.55}, {1.4, -0.5}}]}, ImageSize -> 220]
``````

``````Graphics[{base, Circle[{0.25, 0}, {.58, .38}],
Circle[{0.75, 0}, {.58, .38}], Red, AbsoluteThickness[6],
Line[{{-0.4, -0.5}, {1.4, 0.55}}],
Line[{{-0.4, 0.55}, {1.4, -0.5}}]}, ImageSize -> 220]
``````

Note that I set Frame->True while tweaking these so I could see the coordinates.

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I am looking to programmatically generate an image for a variable number of points. I think I can generalize this, thank you for your help. – tlehman Jan 11 '12 at 6:31
Friggin sweet job on the diagrams! So spot on that I had to laugh. +1 fo sho. – telefunkenvf14 Jan 11 '12 at 7:03
Wonderful! Double-clicking your pictures and moving the objects around one can cover cases that are different from @Tobi's examples e.g. the case where the subset `{1,3}` is an element of the list which requires laying points in a triangle. – kglr Jan 11 '12 at 8:15

To complement Mike's cool diagrams, here is a way to check if an arbitrary finite list of lists is a topology, that is, (1) if it contains the empty set, (2) the base set, (3) closed under finite intersections, and (3) closed under union:

``````topologyQ[x_List] :=
Intersection[x, #] === # & [
Union[
{Union @@ x},
Intersection @@@ Rest@#,
Union @@@ #
] & @ Subsets @ x
]
``````

Applied to the six examples

``````list1 = {{}, {1, 2, 3}};
list2 = {{}, {1}, {1, 2, 3}};
list3 = {{}, {1}, {2}, {1, 2}, {1, 2, 3}};
list4 = {{}, {2}, {1, 2}, {2, 3}, {1, 2, 3}};
list5 = {{}, {2}, {3}, {1, 2, 3}};
list6 = {{}, {1, 2}, {2, 3}, {1, 2, 3}};
``````

like

``````topologyQ /@ {list1, list2, list3, list4, list5, list6}
``````

gives

``````{True, True, True, True, False, False}
``````

EDIT 1: For a further refinement of the formulation, note that the operator

``````topoCover := (Union @@ {Union @@@ #, Intersection @@@ Rest@#} &)@Subsets@# &
``````

gives the collection obtained by taking all unions and intersections of the elements of a collection of sets. A collection of sets `list` is a topology if it is a fixed point of the operator `topoCover`. So one can define an alternative function to check if `list` is topology:

`````` topologyQ2 := (topoCover@# === #) &
``````

If `list` is not a topology, `topoCover` gives the smalles superset of `list` which is a topology. So

``````Complement[topoCover@#,#]&
``````

gives the elements to be added to `list` to make it a topology.

One can also consider largest subset(s) of `list` which is a topology and the element(s) to be deleted from `list` to topologize it. This is done by using

`````` maxTopoSubset := (If[{} == #, None, Last@#] &)@(GatherBy[
Select[Subsets@#, topologyQ], Length[#] &]) &
``````

Applied, for example, to `list6` as

`````` maxTopoSubset@list6
``````

we get the two topologies

`````` {{}, {1, 2}, {1, 2, 3}}, {{}, {2, 3}, {1, 2, 3}}}
``````

To get the elements to be removed to get a topology from `list`, one can use

`````` removeToTopologize :=  Table[Complement[#, Part[maxTopoSubset@#, i]], {i,
Length@maxTopoSubset@#}] &
``````

Using with `list6` as

`````` removeToTopologize@list6
``````

we get

`````` {{{2, 3}}, {{1, 2}}}
``````

that is, removing `{2,3}` or `{1,2}` from `list6` gives a topology.

-
+1 for being so concise! Here I was all proud of myself for doing it in 9 lines. I'll have to read up on the `Rest` function and the `@@` operator, I haven't seen that before. – tlehman Jan 11 '12 at 7:30
`Rest` is simply leaving the first element and taking the rest of the list. `@@` is short for `Apply`. In this usage `And@@Flatten` is replacing the head `List` with the head `And`. Also `topologyQ /@ {list1, list2, list3, list4, list5, list6}` is sufficient. @kguler is `Union@Apply[Union,...]` really necessary in the final line? Shouldn't `Apply[Union,...]` do the job? – Mike Honeychurch Jan 11 '12 at 7:50
@Tobi, thank you. Actually, it took quite a few trial/error iterations to get it working. Had to use `Rest` to get rid of the empty set at the beginning of `Subsets[]` list. Of course, there is still ample room to make it shorter and more elegant. – kglr Jan 11 '12 at 7:52
@Mike, I get, for example, `{{}, {1, 2, 3}, {1, 2, 3}}` from `Apply[Union, Rest@Subsets[list1], 1]`. Need to apply `Union` again to eliminate repeated elements before I check membership. – kglr Jan 11 '12 at 7:58
ok. I overlooked your use of levelspec. Note that `Apply[Union, Rest@Subsets[list1]]` returns `{{},{1,2,3}}` which is what I was actually thinking of when I made the previous comment. – Mike Honeychurch Jan 11 '12 at 8:08