- #1
lreyvega
- 1
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Hi everyone! I have the following problem
X is countable set if and only if the sigma-field 2_{X} is generated by the sets of the form \left\{\omega\right\} with \omega\in X
The easy part is X is countable then...
I'm trying to prove the other part. So, I know that the sigma-field 2_{X} is generated by the sets of the form \left\{\omega\right\} with \omega\in X. This means that 2_{X} can be written as
2_{X}=\cap \sigma_{\alpha}
where \sigma_{\alpha} are all the sigma-fields that contain the family of the singletons. But 2_{X} is the biggest sigma-field that can be constructed in X. That means that \sigma_{\alpha}=2_{X} \forall
\alpha.
Now suppose that X is uncountable. Be the sigma-field \sigma constructed in the following manner:
A\subseteq X is in the \sigma if A is countable or finite or if X\A is countable or finite.
It is clear that this sigma-field contains the class formed by the singletons in X. However, this class it is not 2_{X}, because if X is uncountable exists B\subset uncountable with X\B uncountable. That is, B is not in \sigma. This means that
2_{X} is not equal to \cap \sigma_{\alpha}
So, this is a contradiction and X is numerable.
So, my questions are:
1) Is this proof correct?
2) If it is correct, I think that the critical point in it is this fact I used:
If X is uncountable exists B\subset uncountable with X\B uncountable
How can I prove this? I think that I need to use the axiom of choice, but I have no clue how to do it.
Thanks and sorry for my bad english
Homework Statement
X is countable set if and only if the sigma-field 2_{X} is generated by the sets of the form \left\{\omega\right\} with \omega\in X
Homework Equations
The Attempt at a Solution
The easy part is X is countable then...
I'm trying to prove the other part. So, I know that the sigma-field 2_{X} is generated by the sets of the form \left\{\omega\right\} with \omega\in X. This means that 2_{X} can be written as
2_{X}=\cap \sigma_{\alpha}
where \sigma_{\alpha} are all the sigma-fields that contain the family of the singletons. But 2_{X} is the biggest sigma-field that can be constructed in X. That means that \sigma_{\alpha}=2_{X} \forall
\alpha.
Now suppose that X is uncountable. Be the sigma-field \sigma constructed in the following manner:
A\subseteq X is in the \sigma if A is countable or finite or if X\A is countable or finite.
It is clear that this sigma-field contains the class formed by the singletons in X. However, this class it is not 2_{X}, because if X is uncountable exists B\subset uncountable with X\B uncountable. That is, B is not in \sigma. This means that
2_{X} is not equal to \cap \sigma_{\alpha}
So, this is a contradiction and X is numerable.
So, my questions are:
1) Is this proof correct?
2) If it is correct, I think that the critical point in it is this fact I used:
If X is uncountable exists B\subset uncountable with X\B uncountable
How can I prove this? I think that I need to use the axiom of choice, but I have no clue how to do it.
Thanks and sorry for my bad english
