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MATH1251 Questions HELP (1 Viewer)

1008

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What would be the best approach to do this?
 
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InteGrand

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What would be the best approach to do this?
You could use induction. Have you tried this? (The statement given is really just equivalent to saying that the sequence is strictly decreasing.)
 
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leehuan

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Apparently it is also convergent when x equals to 1/3, or says the answers. But I'm confused as to why this is ok because

 

leehuan

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Oh wait conditional convergence will suffice? Ok thanks, didn't know that
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Best approach to proving this is convergent?

 

InteGrand

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Oh wait conditional convergence will suffice? Ok thanks, didn't know that
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Best approach to proving this is convergent?

Lemma. For all sufficiently large k, ln k < k^{1/6}. (In fact: for any given positive alpha and beta, (ln k)^{beta} will be less than k^{alpha} for all sufficiently large k. And not just less than, but 'little oh' of as k -> oo, in fact.)

Proof. Exercise. (E.g. L'Hôpital's rule to prove the little oh statement, which implies the "power of ln k < power of k" part.)

Now, we can say that for sufficiently large k, the summand (which is positive) is less than 1/(k^{1.5}) (which converges by p-test), so the given series converges by the comparison test.
 
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leehuan

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Lemma. For all sufficiently large k, ln k < sqrt(k).

Proof. Exercise.

Now, we can say that for sufficiently large k, the summand (which is positive) is less than 1/(k^{1.5}) (which converges by p-test), so the given series converges by the comparison test.
Aha guess that'll do. That was basically what I was thinking.
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Also a quickie



So if I want to use the formula for radius of convergence



Should I just ignore the (-1)^k or permit R to be negative?
 

Paradoxica

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Aha guess that'll do. That was basically what I was thinking.
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Also a quickie



So if I want to use the formula for radius of convergence



Should I just ignore the (-1)^k or permit R to be negative?
Negative radius is fine, didn't you deal with polar forms some time ago?
 

InteGrand

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Aha guess that'll do. That was basically what I was thinking.
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Also a quickie



So if I want to use the formula for radius of convergence



Should I just ignore the (-1)^k or permit R to be negative?
The formula is actually with absolute values around the fraction. So the (-1)^k goes away. The radius of convergence can't be negative, it is by definition either 0, a positive real number, or +oo. (Further reading: https://en.wikipedia.org/wiki/Radius_of_convergence )
 
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1008

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You could use induction. Have you tried this? (The statement given is really just equivalent to saying that the sequence is strictly decreasing.)
Sorry for the late reply, figured that one out, thanks :D
 

1008

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These as well, please, if anyone could solve these that would be great. I'll be posting more questions up as exams are roughly in a month...





 
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