Series Convergence: Root and Ratio Test Comparison

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The discussion focuses on determining the convergence of the series -∑(2n-2)!/(n!(n-1)!2^(2n-1)) using the root and ratio tests, both yielding a limit of 1. Participants clarify the series formulation and suggest using partial sums to analyze convergence. The proposed approach involves proving the partial sum S_N = -∑(2n-2)!/(n!(n-1)!2^(2n-1)) converges to 1 as N→∞ through mathematical induction, despite acknowledging the complexity of this method.

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thenewbosco
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to solve this question i need to know whether the following series converges. however both the root test and ratio test give 1.

sum from n=1 to infinity:
\sum\frac{-1(2n-2)!}{n!(n-1)!2^{2n-1}}
 
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Do you mean \sum\frac{(-1)^{n}(2n-2)!}{n!(n-1)!2^{2n-1}} or -\sum\frac{(2n-2)!}{n!(n-1)!2^{2n-1}} ?
 
yes, the second one as you have written it, with the -1 out front
 
this doesn't seem to help me in any way..
 
Does -\sum_{n=1}^{\infty}\frac{(2n-2)!}{n!(n-1)!2^{2n-1}}=-1 help?
 
Try partial sums

Try partial sums:

Prove that:

S_{N}:=-\sum_{n=1}^{N}\frac{(2n-2)!}{n!(n-1)!2^{2n-1}}= \frac{\left( 2N\right)!}{2^{2N}\left( N!\right)^2} -1 = \frac{1}{2^{2N}} \left(\begin{array}{cc}2N\\N\end{array}\right)-1


by induction (I hope induction will work, anyway) where \left(\begin{array}{cc}n\\k\end{array}\right) is a binomial coefficient, and then show that the partial sum S_{N} \rightarrow 1\mbox{ as } N\rightarrow \infty.

But I won't kid you, this is NOT the easy way to do this problem.
 

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