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# solving recurrence examples of form T(n-i) + f(n) [closed]

I've been working on a problem set for a bit now and I seem to have gotten the master method down for recurrence examples. However, I find myself having difficulties with other methods (recurrence trees, substitution). here is the question I am stuck on: T(n) = T(n-2) + n^2 Is there a pattern as follows? n^2 + T(n-2) + T(n-4) +... where it goes until there is no more n left. so around n/2 times and would that mean that n^2 + (n-2)^2 + (n-i) ^2 so the asymptotic bound would be theta(n^2)??

I am honestly taking a shot in the dark here, so I was hoping someone could help guide me in how to approach these questions. perhaps not a direct answer to the question but a hint as to where I should begin would be best.

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## closed as not a real question by woodchips, Sudarshan, CloudyMarble, Sankar Ganesh, Steven PennyFeb 6 '13 at 6:18

It's difficult to tell what is being asked here. This question is ambiguous, vague, incomplete, overly broad, or rhetorical and cannot be reasonably answered in its current form. For help clarifying this question so that it can be reopened, visit the help center.If this question can be reworded to fit the rules in the help center, please edit the question.

T(n-2) or T(n/2)? – YXD Feb 5 '13 at 9:33
@MrE I'm having trouble with T(n-2) I can do the ones that satisfy the requirements for Master method such as T(n/2) + F(n) – wenincode Feb 5 '13 at 9:37
I'm looking at the sum of squares right now, Sum(from k=0 ... n) k^2 = (n(n+1)(2n+1))/6. which I can see how that boils down to O(n^3). Yet I don't see how you concluded that it came down to sum of squares? (sorry this area of study isnot my forte) do you just ignore the constants (the subtractions such as -2 , -4, -i) ? and get sum(k=1...n/2) k^2? – wenincode Feb 5 '13 at 9:52

As you said, the result is going to be n^2 + (n-2)^2 + (n-4)^2 + ...

Intuitively you can feel that because there are a lot (n/2) elements in the sum, it's going to be more than O(n^2) - the same way as 1 + 2 + 3 + ... + n is more than O(n).

One way to prove it is that you can approximate the sum with half of the sum of all the square numbers, for which there is a formula. So it's Theta(n^3).

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ah yes I read some of that page and now I think I see it. so it is approximating the sum with half of the sum of all square numbers because we have n^2 + (n-2)^2 + (n-4)^2... rather than n^2 + (N-1)^2... and thats where you get the SS formula to get theta(n^3). – wenincode Feb 5 '13 at 9:59
yes, the sum of squares of evens (eg: 4^2+2^2) is bigger than the one for odds (3^2+1^2), but if you add one more odd (5^2) to the equation that sum is going to be bigger. Because the total sum is theta(n^3), getting half of the sum is a good enough approximation. – Karoly Horvath Feb 5 '13 at 10:03

Here's how to massage the sum into the result

n^2 + (n-2)^2 + ... + (n -2i) + ...

= {just writing in a different way}

(2n/2) + (2n/2 - 2)^2 + ... + (2n/2 -2i)^2 + ...

= {write m = n/2}

(2m)^2 + (2m-2)^2 + ... (2m - 2i)^2 + ...

= 4 ( m^2 + (m-1)^2 + ... (m-i)^2 ...)

= 4 ( sum (k^2) from k=1 to m)

= 4 ( sum (k^2) from k=1 to n/2)

= (n^3 + 3n^2 + 2n)/6

using the formula

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