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 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:
start with the "base" case --
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.
{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.
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
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
{{}, {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
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