# Recurrence Relation: Finding Big O

I am trying to find the big O bound for the following recurrence relation:

``````T(n) = T(n-1) + n^c, where c >= 1 is a constant
``````

So I've decided to solve this by using iteration:

``````T(n) = T(n-1) + n^c
T(n-1) = T(n-2) + (n-1)^c
T(n) = T(n-2) + n^c + (n-1)^c
T(n-2) = T(n-3) + (n-2)^c
T(n) = T(n-3) + n^c + (n-1)^c + (n-2)^c
T(n) = T(n-k) + n^c + (n-1)^c + .... + (n-k+1)^c

Suppose k = n-1, then:

T(n) = T(1) + n^c + (n-1)^c + (n-n+1+1)^c
T(n) = n^c + (n-1)^c + 2^c + 1
``````

I'm not sure if this is correct however, plus I would really appreciate some guidance as to how to derive Big O from this. Thanks a lot!

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There's no terminating definition for T - presumably T(0) or T(1) are defined as a constant? –  Will A Jul 11 '10 at 23:44
doesn't seem to be one.. i guess assume T(1) = 1 –  Parth Jul 11 '10 at 23:45
I realize there are plenty of web resources for figuring out just about any non subjective question on this site. If a website is worthy of being linked, you should post it as an answer. –  NickLarsen Jul 13 '10 at 3:06

Yes, you are correct:

T(n) = nc + (n-1)c + (n-2)c + … + 3c + 2c + 1,

and this sum is

T(n) = O(nc+1). See e.g. Faulhaber's formula. In fact, you can even determine the constant in the leading term (even if it's not germane to the algorithm's asymptotics): the sum is nc+1/(c+1) + O(c), as you can determine through e.g., using, say, integration.

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"You are correct" is not entirely accurate. He replaces n by k-1 but has only 4 terms (also see edit of question). Also, this is tagged as homework. Please don't just give away the answer. And there is a typo: n^(c+1)/(c+1) + O(n^c) :-) –  Aryabhatta Jul 13 '10 at 13:43
I assumed the ellipsis (…) was missing as a minor oversight (he added them in one place, immediately after your answer presumably, and not in the others), so I added it explicitly in my answer. Homework: I didn't even answer this question till he asked it repeatedly! :-) If someone asks homework questions directly, it's their own loss, IMHO. I cannot even delete this answer because it's marked accepted. –  ShreevatsaR Jul 13 '10 at 14:45

What you have is not correct, but you were on the right track.

``````T(n) = T(n-3) + n^c + (n-1)^c + (n-2)^c
T(n) = T(n-k) + n^c + (n-1)^c + (n-k+1)^c
``````

You cannot just go from the first line to the second line.

As you increase k, the number of terms in the right hand side increases too.

To see that think of writing it this way:

``````T(n) - T(n-1)  = n^c.

T(n-1) - T(n-2) = (n-1)^c
..

T(n-k) - T(n-k-1) = (n-k)^c.

..
T(2) - T(1) = 2^c
``````

What happens if you add these up?

Once you do that, can you see what the answer will be for c=1 and c=2? Can you figure out a pattern for the final answer from there?

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Instead of working you way down from n, how about start by working your way up from 0 (I assume the recursion terminates at 0 and you left that bit out). When you start noticing a fixed point (ie a pattern which repeats the same in all cases) you have a good candidate for an answer. Try proving the answer, e.g. through induction.

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I would start by observing that n^c, whilst of course influenced by the value of n, is not going to be any more complex for n vs. n + 1 - it's c that determines the "runtime" of that particular term. Given that, you can assume (at least I would) that the term has constant runtime and determine how many times the recursion will execute for a given n and you'll get your bound.

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I may have misunderstood what Big-O means - I was thinking in terms of runtime - not mathematically! –  Will A Jul 12 '10 at 0:03

To figure these out, fill out a couple of terms and look for the pattern:

T(1) = 0 + 1^c

T(2) = T(1) + 2^c = 0 + 1^c + 2^c

T(3) = T(2) + 3^c = 0 + 1^c + 2^c + 3^c

T(4) = ...

Now express the pattern in terms of n and you have your answer.

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Ohh, and also only the most dominate term matters. –  NickLarsen Jul 13 '10 at 3:20
Unfortunately the "most dominant term" isn't all that matters, less-dominant terms matter if there are enough of them. See my answer. –  Artelius Jul 13 '10 at 3:39
I completely agree with this, and realize my last statement was misleading. Thank you for the correction. –  NickLarsen Jul 13 '10 at 11:54

Here it is:

``````T(n) = n^c + (n-1)^c + (n-2)^c + ... + 2^c + 1^c
< n^c +     n^c +     n^c + ... + n^c + n^c
= n * n^c
= n^(c+1)
``````

which is O(nc+1).

To show this is a reasonable bound, note that when `c = 1`,

``````T(n) = n + (n-1) + (n-2) + ... + 2 + 1
= n * (n-1) / 2
``````

which is clearly Θ(n2).

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This could just be a misunderstanding on my part, being that I do not work on these types of problems very often, but `O(n^[c + 1]) = O(n^c)`. This is much like `O(cn) = O(n)`. Its based on growth rate, which is still `n` to a constant power. –  NickLarsen Jul 13 '10 at 11:58
@Nick: Yes, it is a misunderstanding on your part. O(n^2) is not O(n). –  ShreevatsaR Jul 13 '10 at 13:14
@ShreevatsaR: I see that corner case, what if you constrain c > 1? –  NickLarsen Jul 13 '10 at 13:31
@Artelius: To show that it is a reasonable bound, consider: postive terms + (n/2)^c + (n/2+1)^c + ... + n^c > (n/2)^c * (n/2). Thus coupled with your earlier estimate, T(n) = Theta(n^(c+1)). So, it is not only reasonable, but accurate. –  Aryabhatta Jul 13 '10 at 13:54
@Nick. c=1 is not a corner case. O(n^(c+1)) = O(n^c) is false for every real c. –  Aryabhatta Jul 13 '10 at 13:56
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