The **exact** time complexity of this algorithm is... `O(F(n))`

where F(N) is nth Fibonacci number. Why? See the explanation below.

Let's prove it by induction. Clearly it holds for the base case (everything is a constant). Why does it hold for F(N)? Let's denote algorithm complexity function as T(N). Then `T(N) = T(N-2) + T(N-1)`

, because you make 2 recursive calls - one with the argument decreased by 1, one decreased by 2. And this time complexity is exactly Fibonacci sequence.

So `F(N)`

is the best estimation you can make but you can also say this is `O(2^n)`

or more precisely `O(phi^n)`

where `phi = (1 + sqrt(5)) / 2 ~= 1.61`

. Why? Because nth Fibonacci number is almost equivalent to `phi ^ n`

.

This bound makes your algorithm *non-polynomial* and very slow for numbers bigger than something around `30`

. You should consider other good algorithms - there are many logarithmic algorithms known for this problem.

`O(phi^n)`

time. – Boris the Spider Sep 21 '13 at 14:44O(phi^n)for example for 200th Fibonacci number? – J.Olufsen Sep 21 '13 at 14:50`O(phi^2)`

. This won't be very accurate. Is this an exercise? – Boris the Spider Sep 21 '13 at 14:56