# Prove log(n) is big-o of (sqrt(n)) [closed]

How to prove log(n) is big-o of (sqrt(n))?

How do I find the c and the n0?

I understand to start, I need to find something that log(n) is smaller to, but I m having a hard time coming up with the example.

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## closed as off topic by Tim Cooper, Julius, Mario, Sam I am, ricksterFeb 15 '13 at 20:28

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This question belongs in the mathematics site. –  Kaz May 16 '12 at 3:34
Or possibly [the Theoretical CS site](cstheory.stackexchange.com). Also good to let people know if you're asking for homework help. –  rickster Feb 15 '13 at 20:28

To solve this problem find a base case: a some value of x for which sqrt(x) is greater than log(x). Then use induction to prove that this is true for all values of x which are larger. If there exists some `a` such that `|f(x)| > |g(x)|` for all `x >= a`, then you know that `g(x)` is `O(f(x))`. `log` and `sqrt` have the nice property that they are monotonically increasing. Once `sqrt` overtakes `log`, `log` never catches up.

I'd like to give the sketch of some kind of proof, but there is no nice mathematics typesetting here like there is in http://mathematics.stackexchange.com so it is going to look ugly.

Suppose sqrt(x) > log(x) for some x. (By log, let us take the natural logarithm, and by sqrt we mean the positive square root).

Show that, necessarily, sqrt(x + epsilon) > log(x + epsilon) for an arbitrarily small epsilon.

sqrt(x + epsilon) can be approximated using sqrt(x) + sqrt'(x)*epsilon: the value of sqrt(x) plus the value of the derivative of sqrt(x) at x, times the epsilon. This is because sqrt is a continuous, smooth function with a derivative over our domain of interest.

Similarly, log(x + epsilon), for infinitesimal epsilon, is log(x) + log'(x)*epsilon.

If you can show that sqrt'(x)*epsilon > log'(x)*epsilon, in other words that sqrt'(x) > log'(x), then you can prove the result. (Because sqrt(x) is bigger than log(x), and you're adding to it something bigger than what you are adding to log(x)).

Now we need those derivatives:

``````sqrt'(x) = 1/(2*sqrt(x))

log'(x) = 1/x.
``````

We can show that 1/(2*sqrt(x)) is larger than 1/x for some x simply by solving the inequality:

``````1/(2*sqrt(x)) > 1/x

x > 2*sqrt(x)

x^2 > 4*x

x^2 - 4x > 0

x(x - 4) > 0

x > 4 || x < 0   /* borrowing C symbol for logical or */
``````

So, for x greater than 4, the derivative of sqrt(x) exceeds the derivative of log(x). Furthermore, at x = 4, sqrt(x) > log(x), by inspection.

So this tells us that an infinitessimal step in x causes a bigger delta in sqrt(x) than it does in log(x), and sqrt(x) is bigger to begin with, thus sqrt(x) is bigger than log(x).

You can think of the derivative as speed. If rabbit is ahead of turtle at time t, and rabbit's speed at time t, and subsequent values of time t, is also greater, then the turtle can never catch the rabbit.

Q.E.D.

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First you need an optimal algorithm to compute a square root. Then, when you have the steps in front of you, you can reason about how the number of steps is related to `N`. Things that proceed by dividing the problem set in half at each step are `ln(N),` so if that's what your algorithm looks like, you're pretty much done as soon as you start.

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