Generally speaking, is the following always true?

log(n) = O(na/(a+1))? s.t. a is any constant positive integer, perhaps very large.

If not, what is the largest value of a for which this statement will hold true?


As functions go, log(n) always grows slower than nany power when n gets large. See https://math.stackexchange.com/questions/1663818/does-the-logarithm-function-grow-slower-than-any-polynomial for proof.

So as long as a is a constant positive integer, it really doesn't matter what its value is, as it will always be possible to find constants C and k such that log(n) <= |C(na/(a+1)| + k, which is the definition of big-O.

However, you can also understand it intuitively: na/(a+1) approaches n as a becomes large. Naturally, log(n) is always O(n).

  • 1
    " it really doesn't matter what the value of a is": it does matter a bit though: will it hold when a is in the interval [-1, 0]? – trincot Oct 11 '16 at 16:57
  • You've misunderstood. He's asking about the complexity of the function log(N), when N gets arbitrarily large. – Malcolm McLean Oct 11 '16 at 17:03
  • @trincot, the OP specifies that a is "any constant positive integer." a cannot be in the interval [-1, 0]. – pymaxion Oct 11 '16 at 18:40
  • @MalcolmMcLean I don't understand the distinction between your comment and the question I answered. – pymaxion Oct 11 '16 at 18:41
  • @pymaxion, so it does matter then. Your statement could be understood to mean that the constraint that the OP put on the variable a is not relevant. – trincot Oct 11 '16 at 18:44

The basic fact is that because of the concavity of the logarithm, it is always below its tangent. So

log(x) <= log(e) + 1/e * (x-e) = x/e


log(n) = O(n).

Now it is only necessary to apply logarithm laws to find

log(n) = 1/c * log(n^c) <= 1/(ce) * n^c

and thus log(n)=O(n^c) for any positive C.


If you mean log(n)∈O(n^(a/(a+1)), yes this is true for all positiv Integers for a, because a/a+1 < 1 => n^(a/(a+1) ∈ O(n) and because of log(n) ∈ O(n) => log(n) ∈ O(n^(a/(a+1))

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