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veirarer

veirarer

Answered question

2022-06-19

A measure μ : B R [ 0 , ] is locally finite if μ ( K ) < for all K compact. Show that any locally finite measure is σ-finite. Give an example of a σ-finite measure on R , which is not locally finite.
Attempt: Since R = n Z [ n , n + 1 ] and each [ n , n + 1 ] is compact, we have μ ( [ n , n + 1 ] ) < for each n and μ is σ-finite. Is this part of the problem correct?
For the second part, I have no idea. I wanted to take counting measure on a collection of subsets of R , but I know this measure is locally finite on the integers and not so with the usual topology. But I know this measure is not sigma finite on R . Any suggestions?

Answer & Explanation

Layla Love

Layla Love

Beginner2022-06-20Added 29 answers

Your solution to the first part is correct. For the second part, e.g. μ ( X ) = m ( tan ( X ( π / 2 , π / 2 ) ) ) where m is the Lebesgue measure.
The intuition is clear: We ignore any part of X outside ( π / 2 , π / 2 ), and since tan is a bijection from ( π / 2 , π / 2 ) to R , the Lebesgue measure on R induces a natural measure on ( π / 2 , π / 2 ). To formally prove this won't be hard. In particular, μ ( [ π / 2 , π / 2 ] ) = , so μ is not locally finite.
If this is not intuitive enough. We can do the following modified version of the counting measure, let A = { 1 , 1 / 2 , 1 / 3 , 1 / 4 , }, and define μ ( X ) = | A X | , then μ is σ-finite but not locally finite as μ ( [ 0 , 1 ] ) = .
Davon Irwin

Davon Irwin

Beginner2022-06-21Added 5 answers

No, your answer to 1. is not completely correct. For σ-additivity, you are in need of disjoint sets, i. e. consider ( n , n + 1 ] (with parenthesis). These sets are not compact themselves, but are subsets of compact sets [ n , n + 1 ]. Now, since μ ( ( n , n + 1 ] ) μ ( [ n , n + 1 ] ), you get the result by an inequality. EDIT: I am wrong.

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