# 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) + ...

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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).

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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.

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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

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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