# Big Oh notation

Just need a confirmation on something real quick. If an algorithm takes `n(n-1)/2` tests to run, is the big oh `O(n^2)`?

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n(n-1)/2 expands to `(n^2 -n) / 2`, that is `(n^2/2) - (n/2)`

`(n^2/2)` and `(n/2)` are the two functions components, of which `n^2/2` dominates. Therefore, we can ignore the `- (n/2)` part.

From `n^2/2` you can safely remove the /2 part in asymptotic notation analysis.

This simplifies to `n^2`

Therefore yes, it is in O(n^2)

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Yes, that is correct.

`n(n-1)/2` expands to `n^2/2 - n/2`:

The linear term `n/2` drops off because it's of lower order. This leaves `n^2/2`. The constant gets absorbed into the big-O, leaving `n^2`.

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Thanks for the help! –  Jay Nov 24 '11 at 20:07
@Jay, you should accept the answer if you believe that is satisfies your question –  dgraziotin Nov 24 '11 at 20:21

Yes:

``````n(n-1)/2 = (n2-n)/2 = O(n^2)
``````
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Yes, it is. `n(n-1)/2` is `(n^2 - n)/2`, which is clearly smaller than `c*n^2` for all `n>=1` if you pick a `c` that's at least 1.

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n(n-1)/2 tests ? You should count the instructions not just the test. So if after every test there are just some instructions the answer is (probably?) yes. Otherwise, let us see the code.

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