# Asymptotic analysis question: sum[log(i)*i^3, {i, n}] is big-theta (log(n)*n^4)

I've got a homework question that's been puzzling me. It asks that you prove that the function Sum[log(i)*i^3, {i, n}) (ie. the sum of log(i)*i^3 from i=1 to n) is big-theta (log(n)*n^4).

I know that Sum[i^3, {i, n}] is ( (n(n+1))/2 )^2 and that Sum[log(i), {i, n}) is log(n!), but I'm not sure if 1) I can treat these two separately since they're part of the same product inside the sum, and 2) how to start getting this into a form that will help me with the proof.

Any help would be really appreciated. Thanks!

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The series looks like this - log 1 + log 2 * 2^3 + log 3 * 3^3....(upto n terms) the sum of which does not converge. So if we integrate it

Integral to (1 to infinity) [ logn * n^3] (integration by parts)

you will get 1/4*logn * n^4 - 1/16* (n^4)

It is clear that the dominating term there is logn*n^4, therefore it belongs to Big Theta(log n * n^4)

The other way you could look at it is -

The series looks like log 1 + log2 * 8 + log 3 * 27......+ log n * n^3. You could think of log n as the term with the highest value, since all logarithmic functions grow at the same rate asymptotically,

You could treat the above series as log n (1 + 2^3 + 3^3...) which is

log n [n^2 ( n + 1)^2]/4

Assuming f(n) = log n * n^4 g(n) = log n [n^2 ( n + 1)^2]/4

You could show that lim (n tends to inf) for f(n)/g(n) will be a constant [applying L'Hopital's rule]

That's another way to prove that the function g(n) belongs to Big Theta (f(n)).

Hope that helps.

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Hint for one part of your solution: how large is the sum of the last two summands of your left sum?

Hint for the second part: If you divide your left side (the sum) by the right side, how many summands to you get? How large is the largest one?

Hint for the first part again: Find a simple lower estimate for the sum from n/2 to n in your first expression.

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Unless I have made another mistake, I want an up-vote now. –  toochin Feb 8 '11 at 2:39
Thanks a lot :) –  toochin Feb 8 '11 at 2:50
I hate to see a grown man cry. Also, I can sympathize with the feeling of having a brilliant insight go completely unrecognized. –  Jim Lewis Feb 8 '11 at 2:57
Now I'm down again. Wonder if it has to do with the answer or with the comments. (Answer is a bit incomplete because if n is uneven, you need to find a lower bound for the sum from (n+1)/2 and then show that (n-1)/2*((n+1)/2)^3) > n^4/16) –  toochin Feb 8 '11 at 12:07
I would if I could my friend, but the reputation gods don't look kindly on me. Thanks for your help! I haven't had time to take a close look at this again, but I think I know where I'm going now. I'll post the solution once I get it worked out. –  cjm Feb 8 '11 at 22:28

Try BigO limit definition and use calculus.

For calculus you might like to use some Computer Algebra System.

In following answer, I've shown, how to do this with Maxima Opensource CAS : Asymptotic Complexity of Logarithms and Powers

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It's easy enough to chuck this into some CAS and get the limit of the quotient of the two, but that doesn't help me learn anything. I was looking for techniques to do this by hand. –  cjm Mar 4 '12 at 20:03
So ,"try BigO limit definition" and use calculus. CAS was just exmaple. You can find many sources, how to calculate limits. For BigO limit definition check : cstheory.stackexchange.com/q/1718/6133 –  Grzegorz Wierzowiecki Mar 5 '12 at 12:34