**Proof**

You model the time function to calculate `Fib(n)`

as sum of time to calculate `Fib(n-1)`

plus the time to calculate `Fib(n-2)`

plus the time to add them together (`O(1)`

).

`T(n<=1) = O(1)`

`T(n) = T(n-1) + T(n-2) + O(1)`

You solve this recurrence relation (using generating functions, for instance) and you'll end up with the answer.

Alternatively, you can draw the recursion tree, which will have depth `n`

and intuitively figure out that this function is asymptotically `O(2`

^{n}`)`

. You can then prove your conjecture by induction.

Base: `n = 1`

is obvious

Assume `T(n-1) = O(2`

^{n-1}`)`

, *therefore*

`T(n) = T(n-1) + T(n-2) + O(1)`

*which is equal to*

`T(n) = O(2`

^{n-1}`) + O(2`

^{n-2}`) + O(1) = O(2`

^{n}`)`

**Iterative version**

*Note that even this implementation is only suitable for small values of n, since the Fibonacci function grows exponentially and 32-bit signed Java integers can only hold the first 46 Fibonacci numbers*

```
int prev1=0, prev2=1;
for(int i=0; i<n; i++) {
int savePrev1 = prev1;
prev1 = prev2;
prev2 = savePrev1 + prev2;
}
return prev1;
```