|
||
|
Title: measure theory .... Post by trusure on Oct 12th, 2009, 7:08pm I just proved the following result: if (1) f_n is a sequence which converges to f a.e., (2) f_n>=0, and lebesgue measurable on R. (3) integral(f) is finite, and (4) integral (f_n) converges to integral (f) then: integral (f_n) converges to integral (f) over any measurable set A. (note: the integration is Lebesgue integral) Now, I'm looking for a counterexample that this result is not true if integral (f) is infinity. so.... any one can help me .... thanks for helping in advance |
||
|
Title: Re: measure theory .... Post by Obob on Oct 12th, 2009, 9:30pm Let fn(x) = max (1/x2,1/n) on the whole real line. |
||
|
Title: Re: measure theory .... Post by trusure on Oct 12th, 2009, 10:29pm ok, so we have f_n ---> f=1/x^2, but integral of f over R is finite =0, ??!! moreover, what about the set A we will use to get a contradiction ? |
||
|
Title: Re: measure theory .... Post by Obob on Oct 13th, 2009, 5:18am I'm guessing this is homework, so you need to fill in some of the details. And it is definitely not true that the integral of 1/x^2 over R is finite (let alone zero). How on earth could it be zero? It is a function that is strictly positive everywhere. There's a couple other examples that fail for the same reason: Let your measure space X consist of two points p & q, both with infinite measure. Put f_n(p) = 1, f_n(q) = 1/n. Or let your measure space X be a disjoint union of two smaller spaces A and B, where A has infinite measure and B has positive measure. Let g be a function on B with infinite integral, and define f_n(a) = 1/n for a in A, f_n(b) = g(b) for b in B. The first example I gave can be seen as being essentially equivalent to the second construction here. |
||
|
Powered by YaBB 1 Gold - SP 1.4! Forum software copyright © 2000-2004 Yet another Bulletin Board |