Closed set as infinite intersection of open sets

lonewolf5999
Messages
33
Reaction score
0
This is not a homework problem, just something I was thinking about. In a general metric space, is it true that every closed set can be expressed as the intersection of an infinite collection of open sets?

I don't really know where to begin. Since the finite intersection of open sets is open, and the infinite intersection of open sets may or may not be open or closed, this suggests to me that the statement may not be true; however, I'm not sure how I would use this fact to construct a counter-example. Any help is much appreciated!
 
Physics news on Phys.org
The answer is yes. Every closed set can be written as a countable intersection of open sets in a metric space. (this is not true anymore in an arbitrary topological space)

The reason is this: take a closed set F. We have a continuous function f(x)=d(x,F). Notice that f^{-1}(0)=F.
Of course, we have that \{0\}=\bigcap_{n>0} ]-1/n,1/n[, thus

F=\bigcap_{n>0} f^{-1}(]-1/n,1/n[)
 
Thanks for the reply. I hope you can clarify a couple of points in your answer, however. When you say "We have a continuous function f(x)=d(x,F)," am I correct in saying that you mean d(x,F) = inf{d(x,f): f lying in F}?

Also, what do you mean by ]-1/n,1/n[ ? Is it something like an open neighbourhood of radius 1/n around the zero element, and if so, is there any reason why you write it that way as opposed to (-1/n, 1/n)?
 
lonewolf5999 said:
Thanks for the reply. I hope you can clarify a couple of points in your answer, however. When you say "We have a continuous function f(x)=d(x,F)," am I correct in saying that you mean d(x,F) = inf{d(x,f): f lying in F}?

Yes.

Also, what do you mean by ]-1/n,1/n[ ? Is it something like an open neighbourhood of radius 1/n around the zero element, and if so, is there any reason why you write it that way as opposed to (-1/n, 1/n)?

I meant (-1/n,1/n). But I always write ]-1/n,1/n[. It's an accepted notation.
 
Ok, thanks very much for the help and the quick reply!
 

Thread '2-sphere intrinsic definition by gluing disks' boundaries'

A sphere as topological manifold can be defined by gluing together the boundary of two disk. Basically one starts assigning each disk the subspace topology from ##\mathbb R^2## and then taking the quotient topology obtained by gluing their boundaries. Starting from the above definition of 2-sphere as topological manifold, shows that it is homeomorphic to the "embedded" sphere understood as subset of ##\mathbb R^3## in the subspace topology.
View full post »

Similar threads

MHB The Set of Borel Sets .... Axler Pages 28-29 .... ....
Replies
2
Views
2K
I The Set of Borel Sets .... Axler Pages 28-29 .... ....
Replies
2
Views
4K
I Dyadic cubes generate Borel sigma algebra of subset
Replies
2
Views
1K
I Collection of finite unions of half-open intervals form an algebra
Replies
3
Views
3K
I Confused by proof in Hocking and Young
Replies
4
Views
623
I Open balls dense in closed balls in Euclidean space
Replies
2
Views
2K
MHB Proving Topology in X: A Look at Union & Intersection
Replies
2
Views
2K
B Topological neigborhoods that are not intervals in the real line?
Replies
15
Views
2K
I An open set can be a closed interval?
Replies
12
Views
3K
MHB Every Closed Set in R has a Countable Dense Subset
Replies
7
Views
4K

Hot Threads

Recent Insights

Back
Top