# Rates in algorithm analysis? [closed]

WHY do logarithms grow slower than any polynomial? What is the (understandable) proof for this?

Similarly,

WHY do exponentials always grow faster than any polynomial?

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Step 1 -- draw the curves on graph paper. Step 2 -- look at the curves. What are you really asking? Why the shapes are the way they are? –  S.Lott Jan 11 '12 at 19:06

## closed as off topic by driis, 500 - Internal Server Error, PengOne, Robert Harvey♦Jan 12 '12 at 0:31

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EDIT: This answer is essentially doing what PengOne said.

We take the limit of

``````log_2(x) / x^p
``````

for constant p > 0 and show that the limit is zero. Since both log_2(x) and x^p go to infinity as x grows without bound, we apply l'Hopital's rule. This means our limit is the same as the limit of

``````1/(x*ln2) / p*x^(p-1)
``````

Using simple rules of fractions, we reduce this to

``````1 / (p * x^p * ln2)
``````

Since the denominator goes to infinity while the numerator is constant, we can evaluate the limit - it's zero, which means that log_2(x) grows asymptotically more slowly than x^p, regardless of the (positive) value of p.

EDIT2:

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Given two (nonnegative) real-valued functions `f` and `g`, you want to compute

``````lim_{x -> infinity} f(x) / g(x)
``````

This limit is:

• `0` if and only if `f` grows slower than `g`
• `infinity` if and only if `f` grows faster than `g`
• `c` for some constant `0 < c < infinity` if and only if `f` and `g` grow at the same rate

Now you can take any examples you like and compute the limits to see which grows faster.

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