Closure of an open ball and separable space?

In summary, the statement is that in a metric space, a closed ball is also a closed ball of a different radius, but this may not always be the case.
  • #1
adityatatu
15
0
1) In R3 closure of an open ball is a closed ball, but this may not hold in general metric spaces.
Can somebody give an example explaining the above statement?

2) what is a separable space?
some good references are welcome.

thanks for your help in advance.
aditya.
www.geocities.com/aditya_tatu
 
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  • #2
a discrete metric space is just the example you're in need of.
to be more precise the metric is defined as d(x,y) = 0 if x=y and
1 if x is not equal to y.
after that you just need to see any open ball in the space.
 
  • #3
2)A separable space is a metric space with a
countable dense subset.
Reference: "Dictionary of analysis, calculus and differential equations"
 
  • #4
the answer above is not quite precise enough to be correct, nor is the question. i.e. it is true that in a discrete metric space one can find open blass of form: {all points closer than r to p} whose closure is not the closed ball {all points at distance at most r from p}. nonetheless the closure may equal a closed ball defined by a different radius. for example although the closure of the open ball of radius one about p is not the closed ball of radius one, it is the closed ball of radius 1/2.

one does not need any fancy space to get examples. just take the real line and omit say the interval (1,2). then the closure of the open ball of radius 2 about 0 is no longer the closed ball of radius 2 about 0.
 
  • #5
mathwonk said:
one does not need any fancy space to get examples. just take the real line and omit say the interval (1,2). then the closure of the open ball of radius 2 about 0 is no longer the closed ball of radius 2 about 0.

Because the closed ball of radius 2 includes 2, and the closure of this open ball does not, this closure is not the closed ball of radius 2. However,the closure of the set is,for example, the closed ball of radius 1.5 about -0.5 -- an example of the problem that you described with discrete topologies.

This is essentially the same solution but it resolves that issue.
Consider the a plane, but remove the subset where [itex]x\in(1,2)[/itex]. Now, under the usual topology, the open ball of radius 2 about 0 has a closure that is not a closed ball.
 
  • #6
i never claimed i was giving an example of an open ball whose closure was not any closed ball. i was just giving an easier version of mansi's example of one whose closure was not the closed ball of the same radius. i was not interested enough in the problem to try to think of an open ball whose closure was not any closed ball.

in any event i did not think of your nice example.
 
  • #7
mathwonk said:
I was not interested enough in the problem to try to think of an open ball whose closure was not any closed ball.

Ah, I see. The original post had 'not a closed ball' rather than 'not a closed ball of the same radius', and I thought you were referring to that with the comment about closed balls of a different radius.

In any event i did not think of your nice example.
Thank you.
 

1. What is the definition of closure of an open ball?

The closure of an open ball is the set of all points that are either in the open ball or are limit points of the open ball. In other words, it is the smallest closed set that contains the open ball.

2. How is the closure of an open ball related to continuity?

The closure of an open ball is closely related to continuity in the sense that a function is continuous at a point if and only if the image of every open ball around that point is contained within the closure of the function's image at that point.

3. Can the closure of an open ball be uncountable?

Yes, the closure of an open ball can be uncountable. This can happen in infinite-dimensional spaces, where the open ball can contain an uncountable number of points and its closure would also be uncountable.

4. What are some properties of separable spaces?

Some properties of separable spaces include the existence of a countable dense subset, every open set being a union of countably many open balls, and the existence of a countable basis for the topology.

5. How are separable spaces used in mathematics?

Separable spaces are used in mathematics to study various concepts in analysis, such as continuity, convergence, and completeness. They also have applications in other areas of mathematics, such as functional analysis, topology, and measure theory.

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