Talk:Cantor cube

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Dimension

Latest comment: 17 years ago4 comments2 people in discussion

The Cantor cube ${\displaystyle 2^{\omega }}$  can be given a topology where its not zero dimensional (the natural topology on the reals, of course, giving you a one-dimensional space). This article, as well as the Cantor space article, fail to discuss the topology imposed on the set: its zero dim only if the discrete topology is used.

Similarly, giving ${\displaystyle 2^{1}=\{0,1\}}$  the topology ${\displaystyle \{\{0\},\{0,1\}\}}$  makes it not Hausdorf (and not discrete). These issues should be clarified as otherwise its misleading.

Similarly, a discussion of topology w.r.t. group operations is required. For example, I have no clue what the group structure is intended for ${\displaystyle 2^{1}=\{0,1\}}$  if the topology ${\displaystyle \{\{0\},\{0,1\}\}}$  is intended, since clearly, this topology is incompatible with the permutation of two objects... linas 16:03, 18 December 2006 (UTC)Reply

I'm certain the product topology is meant; I can't honestly recall what the source says, but it makes sense. I'm also pretty sure that I wouldn't have misstated Schepin's theorem by leaving out a restriction on the zero-dimensionality of the spaces. So I'll just slide that in... Melchoir 19:05, 18 December 2006 (UTC)Reply

Yeah, OK, it'll do for now; I've been reading literature in ergodic theory that is remarkably sloppy in this way; its irritating, on the one hand, but also good, because it gives me something to work on :-) linas 04:08, 20 December 2006 (UTC)Reply

Well, maybe you can add something later on! Especially if you figure out where precisely the Hausdorff condition goes, speaking of sloppiness... Melchoir 04:32, 20 December 2006 (UTC)Reply