# Series Summation to calculate algorithm complexity

I have an algorithm, and I need to calculate its complexity. I'm close to the answer but I have a little math problem: what is the summation formula of the series

½(n4+n3) where the pattern of n is 1, 2, 4, 8, ... so the series becomes:

½(14+13) + ½(24+23) + ½(44+43) + ½(84+83) + ...

-
It looks like the complexity is O(n^4). – Adam Liss May 4 '12 at 1:04
yes.. but I need the exact formula – VEGA May 4 '12 at 1:06
I think you have it. There may not be a closed-form solution. You might be better off asking on a math site rather than a programming site. – Adam Liss May 4 '12 at 1:31

It might help to express n as 2^k for k=0,1,2...

Substitute that into your original formula to get terms of the form (16^k + 8^k)/2.

You can break this up into two separate sums (one with base 16 and one with base 8), each of which is a geometric series.

S1 = 1/2(16^0 + 16^1 + 16^2 + ...)

S2 = 1/2(8^0 + 8^1 + 8^2 + ...)

The J-th partial sum of a geometric series is a(1-r^J)/(1-r) where a is the initial value and r the ratio between successive terms. For S1, a=1/2, r=16. For S2, a=1/2, r=8.

Multiply it out and I believe you will find that the sum of the first J terms is O(16^J).

-

½ Ʃ ((2r)4+(2r)3) from r=1 to n

(Sorry for the ugly math; there's no LaTeX here.)

The result is 16/15 16n + 8/7 8n - 232/105

You don't need the exact formula. All you need to know is that this is an O(16n) algorithm.

-
thank you ... the link you provide was very helpful – VEGA May 4 '12 at 16:10

thanks to all of u.. the final formula which I was looking for (based on your works) was :

((1/15 2^(4(log2(n)+1))  +  8^(log2(n)+1)/7  -232/105)/2) + 1

this will gives the same result as the program which runs the algorithm

-

looks like your series does not converge ... that is, the summation is infinity. maybe your formula is wrong or you asked the question wrong.

-
Theta notation for f(n) ("big O") doesn't require the series to converge. It just requires the ratio of f(n) to g(n) to converge, where g(n) is some arbitrary function of n. – Li-aung Yip May 4 '12 at 2:42
I suppose I don't understand his notation or technique. The sum of the series he listed is infinity. – les2 May 4 '12 at 3:50
Yes, that series goes to infinity - but the idea is to quantify how fast it goes to infinity. See en.wikipedia.org/wiki/Big_O_notation or rob-bell.net/2009/06/a-beginners-guide-to-big-o-notation – Li-aung Yip May 4 '12 at 4:08
I know what big O is, as well a little o and theta notation. I have not seen "series summation" used to calculate it. I'll look it up in my copy of the CLRS book to refresh when I get a chance. :) – les2 May 5 '12 at 15:54
If you have CLRS 3E, you want Appendix A (p. 1145.) – Li-aung Yip May 5 '12 at 16:24