# Recurrence Relations: Proving (n/2) + (n/2) = O(n)

So say I have an algorithm like this:

``````void dummy_algorithm(int a[]) {
int center = floor(a.length/2);
//For reference purposes: Loop 1
for(int i = 0; i < center; i++) {
//The best code you've ever seen
}
//Loop 2
for(int j = center + 1; j < a.length; j++) {
//Slightly less awesome code
}
}
``````

It's pretty basic stuff. I know both loops iterate through one half of the array, thus giving each an (n/2) complexity. However, the total work the method does is obviously O(n).

So, my question is: How do I prove (via a recurrence relation) that this algorithm is O(n)? Or am I wrong on this altogether?

Note: I cannot combine the two loops into one. They preform actions that eventually go into recursive calls. Anything else you can think of isn't allowed. There are a lot of constraints on this problem.

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Do you really need to prove that O(n/2 + n/2) is in O(n)? It's what I'd call trivial. –  keyser Nov 1 '12 at 16:43
Your code uses two loops, so assuming the content of the loops are both `O(n)`, then you actually have `O(n) + O(n)`, which is just `O(2n)` which is the same as `O(n)`. –  Niet the Dark Absol Nov 1 '12 at 16:44
A recurrence relation is for analyzing a recursive function. –  btilly Nov 1 '12 at 16:47

If you are really looking for a proof that O(x) + O(y) = O(x+y), it would work along these lines:

R1 ∈ O(x) ∧ R2 ∈ O(y)
⇒ ∃ a. R1 < ax ∧ ∃ b. R2 < by
⇒ ∃ a, b. R1 < ax ∧ R2 < by
⇒ ∃ a, b. R1+R2 < ax + by
⇒ ∃ a, b. c=max(a,b) ∧ R1+R2 < cx + cy
⇒ ∃ c. R1+R2 < c(x+y)
⇒ R1+R2 ∈ O(x+y)

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This only shows O(x) + O(y) \subseteq O(x+y), but the other direction is shown analogously. Hence +1. –  DaveFar Nov 1 '12 at 17:06
Thanks guys! Provided much need clarity! –  Taylor Jones Nov 1 '12 at 20:13
``````  (N/2) + (N/2)
= 2*(N/2)
= 2N/2
= N
``````
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asymptotic math doesn't work quite like that. –  Niet the Dark Absol Nov 1 '12 at 16:44
@Kolink Well almost (maybe not when proving, but when looking for an answer). –  keyser Nov 1 '12 at 16:47
@Kolink `O(N/2)` with all standard algebra rules is perfectly valid asymptotic math. It just happens to be the same as `O(N)`. –  btilly Nov 1 '12 at 16:48
O(N) + O(N) is not O(2N). It is still O(N). –  Sani Huttunen Nov 1 '12 at 16:56
@Sani: It is both, since O(2N) = O(N). Ignoring constant factors is the whole reason d'etre of big-O.... –  DaveFar Nov 1 '12 at 17:08

The time complexity (and whether you need a recurrence relation) depends on what you do in the loops, i.e. what the complexity of

``````//The best code you've ever seen (*complexity1*)
``````

and

`````` //Slightly less awesome code (*complexity2*)
``````

is.

If each iteration only requires a constant amount of time, i.e. complexity1 and complexity2 in O(1), then the total complexity will be n*O(1) = O(n). This shows what the Big-O-Notation really does: abstract away from constant factors such as complexity1 and complexity2.

If each iteration requires O(f(n)), then your total time complexity will be O(n*f(n)).

If each iteration makes a recursive call, i.e. calls `dummy_algorithm` with a smaller parameter, you do need a recurrence relation to compute the time complexity. How the recurrence relation looks like depends on how often you make recursive calls and with what parameter. http://en.wikipedia.org/wiki/Recurrence_relation shows you how to find and solve the appropriate recurrence relation.

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