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I am having some trouble, finding the lower bound for this series :

S = lg(n-2) + 2lg(n-3) + 3lg(n-4) + ... + (n-2)lg2.

The upper bound as I have figured out (and I explain below) is O (N^2 . lgN) Could you help me in finding out the lower bound on this.

My proof for the upper bound goes as :

S = lg [ (n-2)* (n-3)^2 * (n-4)^3 *.. *2^(n-2) ] = O ( lg n^(1+2+3+..+(n-1) ) = O ( n^2*log(n) )


Just a random thought. Can I assume the series to be closely approximated by Integral (xLogx), which happens to be O (X^2. lgX) ?? But this too, would give only an upper bound and not a lower bound.

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closed as off topic by Greg Hewgill, Joe, Kirk Woll, svick, Neil Knight Aug 26 '11 at 21:54

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Stack Overflow is for programming questions. Please consider math.stackexchange.com. –  Greg Hewgill Aug 26 '11 at 19:35
It's more of a Complexity analysis, which a good programmer must be aware of. –  n0nChun Aug 26 '11 at 19:37
@n0nChun: I believe Greg meant that there's a difference between computer programming and computer science. –  Blazemonger Aug 26 '11 at 19:41
That's true, but if you want answers more specifically focused on your question, you may want to consider posting this question on a different site. Perhaps cstheory.stackexchange.com could be an option. –  Greg Hewgill Aug 26 '11 at 19:42
I agree, there. But, If the community thinks it needs to be migrated, then be it! :) –  n0nChun Aug 26 '11 at 19:43

1 Answer 1

up vote 2 down vote accepted

lg(n-2) + 2lg(n-3) + 3lg(n-4) + ... + (n-2)lg2 > lg(n-2) + 2 lg(n-3) + ... + (n/2)log(n/2) =
= lg [(n-2) * (n-3)^2 * ... * (n/2)^(n/2)] > lg[(n/2) * (n/2)^2 * ... * (n/2)^(n/2)] =
= lg [(n/2)^(1+2+...+n/2)] = lg [ (n/2) ^ [(n^2)/4] = [(n^2)/4] * lg(n/2) = omega(n^2 * lgn)

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Nicely done,Amit. And as a coincidence, my name is Amit too :) –  n0nChun Aug 26 '11 at 20:35
@n0nchun: you welcome, the trick in these things is using only a part of the series where you can bound all elements to something convinient to you. –  amit Aug 28 '11 at 7:51

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