Talk:Infinity-Borel set
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[edit] (Formerly) Disputed
Um, so actually I wrote this article, and no one else has touched it, so really I'm arguing with myself here. But I thought about it and I'm not sure my definition is right. On the other hand, if it is right, it's (I think) easier to follow than any alternative I can think of, so I don't want to jump the gun. But I also don't want to mislead anyone.
Here's the issue; maybe someone can help me out: The ∞-Borel sets are the ones that have ∞-Borel codes. An ∞-Borel code is something that codes up the way you build an ∞-Borel set by starting with open sets (each basic open set gets a code), and then iterating the operations of complementation and wellordered union (there's a code for the complement of a coded set, and a code for the union of a sequence of coded sets).
Problem is--is the class of thus-coded sets in fact closed under wellordered union? To prove it, you'd seem to need ACα, if your sequence of sets to be unioned up has length α, in order to choose a Borel code for each of the sets in the sequence, so you can form the new Borel code.
Any help appreciated. --Trovatore 04:21, 15 July 2005 (UTC)
[edit] Fixed
So the definition now in place is harder to follow, and it's got a lot of LaTeX that simply cannot be displayed if anyone is expected to read the thing. But it does have the advantage of being correct. --Trovatore 02:20, 16 July 2005 (UTC)
[edit] Alternative definition
So I thought of another approach: Dispense with the codes, and perform the transfinite iteration directly on the sets. Something like this:
- For each ordinal α define by transfinite recursion Bα as follows:
- B0 is the collection of all open subsets of X.
- For a given even ordinal α, Bα+1 is the union of Bα with the set of all complements of sets in Bα.
- For a given even ordinal α, Bα+2 is the set of all wellordered unions of sets in Bα+1.
- For a given limit ordinal λ, Bλ is the union of all Bα for α<λ
- It follows from the Burali-Forti paradox that there must be some ordinal α such that Bβ equals Bα for every β>α. For this value of α, Bα is the collection of ∞-Borel sets.
Whaddaya think? Is it clearer than the definition with codes? I did leave more out in this alternative version (e.g. I didn't really say what a wellordered union is, and it takes a little argument to see that clause 3. above gives you a set at all, rather than a proper class). Also the code notion is important. --Trovatore 02:49, 16 July 2005 (UTC)
Whoops. It is clearer, but it's wrong. Can't prove without AC that every set as defined above has an ∞-Borel code; same error as before. --Trovatore 03:06, 16 July 2005 (UTC)