# Big O proof with sqrt and log

I am having trouble figuring out how to prove that

``````t(n) = sqrt(31n + 12n log n + 57)
``````

is

``````O(sqrt(n) log n)
``````

I haven't had to deal with square root's in big O notation yet so I am having lots of trouble with this! Any help is greatly appreciated :)

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Is this homework? If so, please add that tag. –  Ted Hopp Feb 24 '11 at 19:50
not homework! just practice so i didnt think that tag was necessary, but thanks! –  deedex11 Feb 24 '11 at 20:39

Big O notation is about how algorithm characteristics (clock time taken, memory use, processing time) grow with the size of the problem.

Constant factors get discarded because they don't affect how the value scales.

Minor terms also get discarded because they end up having next to no effect.

``````sqrt(31n + 12nlogn + 57)
``````

immediately simplifies to

``````sqrt(n log n)
``````

Square roots distribute, like other kinds of multiplication and division, so this can be straightforwardedly converted to:

``````sqrt(n) sqrt(log n)
``````

Since logs convert multiplication into addition (this is why slide rules work), this becomes:

``````sqrt(n) log (n/2)
``````

Again, we discard constants, because we're interested in the class of behaviour

``````sqrt(n) log n
``````

Update

As has been correctly pointed out,

``````sqrt(n) sqrt(log n)
``````

does not become

``````sqrt(n) log (n/2)
``````

So the end of my derivation is wrong.

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sqrt(log n) isn't log(n/2). –  Chris Nash Feb 24 '11 at 20:00
@Chris Darn. You're right. Got my operations reversed. Classic case of seeing what I wanted to, to end up at a predefined point. Thanks for the catch. –  Bevan Feb 24 '11 at 20:06
No worries. I figure it's a big O, so we don't have to try too hard for that last bit... sqrt(log n) is clearly smaller than log n eventually :) –  Chris Nash Feb 24 '11 at 20:30
sqrt(log n) = (log n)^ (1/2) = (1/2) * (log n) –  Silvia Mar 22 '12 at 5:30
@Silvia: Wouldn't that only be true if it were log(n^(1/2))? Not (log n)^(1/2)? –  shj Apr 16 '12 at 2:24

Start by finding the largest-degree factor inside of the `sqrt()`, which would be `12nlogn`. The largest-degree factor makes all the other factors irrelevant in big O terms, so it becomes `O(sqrt(12nlogn))`. A constant factor is also irrelevant, so it becomes `O(sqrt(nlogn))`. Then I suppose you can make the argument this is equal to `O(sqrt(n) * sqrt(logn))`, or `O(sqrt(n) * log(n)^(1/2))`, and eliminate the power on `logn` to get `O(sqrt(n)logn)`. But I don't know what the technical justification would be for that last step, because if you can turn `sqrt(logn)` into `logn`, why can't you turn `sqrt(n)` into `n`?

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Hint: Consider the leading terms of the expansion of sqrt(1 + x) for |x| < 1.

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