[measure theory] measurable function f and simple function g

AI Thread Summary
A function f:X->R is measurable and bounded if, for every ε > 0, there exists a simple function g such that |f(x) - g(x)| ≤ ε for all x in X. Since simple functions are bounded, this implies that f must also be bounded. The discussion raises the question of whether a measurable function g can always be found for each ε, which is crucial for establishing the measurability of f. The pointwise limits of measurable functions are also noted to be measurable, suggesting a pathway to understanding the problem. Overall, the relationship between simple functions and the measurability of f is central to resolving the inquiry.
rahl___
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Hi everyone!

my problem:

If f:X->R is a function that for each \epsilon > 0 exists such simple function g satisfying |f(x)-g(x)| <= \epsilon for each x\in X, then f is measurable and bounded.

since every simple function is bounded, we at once know, that either is our function f, cause:
- \epsilon + g(x) <= f(x) <= \epsilon + g(x), so that's obviously not the problem here. this whole measure stuff doesn't get into my intuition and I don't have any idea how to try to solve this task. if i knew, that for each \epsilon i could get a measurable function g, it would be obvious, that f is measurable too [wouldn't it?], but can i really always have a measurable function g?

i would be very grateful for any hints. hope my english isn't terrible enough to disturb the sense of this post.

rahl.
 
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Think about why pointwise limits of measurable functions ought to be measurable. Also, hopefully those simple functions are measurable.
 

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