I believe it's not. The definition is that:

```
log(n) >= c*n for some n = x, and all n > x
```

The reason I think it's not is that the rate of growth of c*n = c. The rate of growth of log(n) = 1/n. So, as n-> infinity, the rate of growth of n approaches 0, whereas c, the rate of growth of c*n, is constant. Given that eventually log(n) will eventually grow slower than any n*c, where c > 0, n*c will outgrow log(n).

So, a few questions.

- Can I assume c > 0 from the definition of big omega?
- Is my above intuition correct?
- I'm conflicted about my proof above. Because for very small c's, log(n) = cn very early, my assumption above implies that they would intersect again, which means log(n) = cn has more than one solution, which seems wrong.

I'm very confused and appreciate the help!

algorithms, not abstract functions. For example, there are algorithms that can compute`log(n)`

(for a finite set of input values of`n`

) in Ω(1) -- your FPU probably contains one in the form of a lookup table. – Daniel Pryden Jun 4 '11 at 22:18