Integral over a set of measure 0

Boot20
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Is the integral over a set of measure zero always equals to zero? Can the integral be undefined?
 
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It may be undefined if the function itself is peculiar with infinity as its value. For ordinary functions the integral will be 0.
 
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mathman said:
It may be undefined if the function itself is peculiar with infinity as its value. For ordinary functions the integral will be 0.

Sorry, I have the question that, if Lebesgue integration, they always define the convention \infty \cdot 0 = 0, so, in this case, even the function takes \infty in a set of measure 0, the integral is still 0?
 
Convention is an easy way out.
 
For Lebesgue integration, that the integral over a set of measure zero is a rather trivial theorem, following from the fact that all simple functions have integral zero -- so via (what I believe is) the usual formulation, it doesn't even need to be treated as a special case.


Riemann integration assumes the function is real-valued, so it doesn't even apply if you are considering extended-real-number-valued functions that take on the values +\infty or -\infty.
 
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But apparently to me \infty \cdot 0 = 0 should be adopted
Else, if f admit \infty on set A of measure 0, we may use f_{n} = n on A to approximate f from below, then, the integral of f_{n} is zero, by monotone convergence theorem, the integral of f should be zero as well. If we do not define \infty \cdot 0 = 0, we may get inconsistency in this case?
 
wayneckm said:
But apparently to me \infty \cdot 0 = 0 should be adopted
Else, if f admit \infty on set A of measure 0, we may use f_{n} = n on A to approximate f from below, then, the integral of f_{n} is zero, by monotone convergence theorem, the integral of f should be zero as well. If we do not define \infty \cdot 0 = 0, we may get inconsistency in this case?

But what if the f_{n} are defined over sets of measure non-zero, but that the sum of the measure of those sets converges to zero?
 
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Boot20 said:
But what if the f_{n} are defined over sets of measure noe intgen-zero, but that the sum of the measure of those sets converges to zero?

Sorry that I cannot get your idea exactly. Or can you tell me explicitly what is the function f to be integrated?
 

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