# Big-O of equations [closed]

I have an assignment where i have to find Big-O of certain functions. I know how to find it in a function such as

``````  n^4 + 3n^3 + 49
``````

and also like this

``````  n log n.
``````

However, I'm not sure how to find the complexity where, for instance, where quadratics and logarithms are combined, ex:

``````  3n^2 + 400 n log n + 100.
``````

Any nudge in the right direction would be great!

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## closed as off topic by JonH, Ken White, middaparka, Wooble, John KugelmanOct 23 '12 at 18:01

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With Big-O notation you drop everything but the biggest part. Say we have a function that runs in N^N + 20 iterations. Big-O tell us that this is a O(N^N) complexity.

Another example could be N^N + 100N + N, we drop 100N and N meaning this is O(N^N)

Why do we drop these?

Imagine if N = 1,000,000,000,000. In the first example the 20 is nothing next to the N^N part. It so insignificant that we don't care about 20 extra iterations. The same goes for the second example. N^N is so much bigger than 100N and N that we drop them.

Given n^4 + 3n^3 + 49...

this would be O(n^4) because we don't care about 49 - it's nothing. for 3n^3 we boil that down to n^3 because 3 X n^3 doesn't really matter when n = 100 bagillion.

Given n log n...

this would just be O(n log n)

Final example....

After dropping insignificant terms we're left with n^2 + n log n. Which of these is the largest, most significant term as n gets bigger and bigger? It's n^2. As n gets larger, n log n is much smaller than n^2

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In O(n) there should be just the dominant term, even though you occationally see O(n*logn + nloglogn)

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When they are combined via addition, you take the one with greatest complexity:

``````3n^2