I just tried implementing code (in Java) for various means by which the nth term of the Fibonacci sequence can be computed and I'm hoping to verify what I've learnt.

The iterative implementation is as follows:

```
public int iterativeFibonacci(int n)
{
if ( n == 1 ) return 0;
else if ( n == 2 ) return 1;
int i = 0, j = 1, sum = 0;
for ( ; (n-2) != 0; --n )
{
sum = i + j;
i = j;
j = sum;
}
return sum;
}
```

The recursive implementation is as follows :-

```
public int recursiveFibonacci(int n)
{
if ( n == 1 ) return 0;
else if ( n == 2 ) return 1;
return recursiveFibonacci(n-1) + recursiveFibonacci(n-2);
}
```

The memoized implementation is as follows :-

```
public int memoizedFibonacci(int n)
{
if ( n <= 0 ) return -1;
else if ( n == 1 ) return 0;
else if ( n == 2 ) return 1;
if ( memory[n-1] == 0 )
memory[n-1] = memoizedFibonacci(n-1);
if ( memory[n-2] == 0 )
memory[n-2] = memoizedFibonacci(n-2);
return memory[n-1]+memory[n-2];
}
```

I'm having a bit of a doubt when trying to figure out the Big-O of these implementations. I believe the *iterative implementation to be O(n)* as it loops through N-2 times.

In the recursive function, there are values recomputed, hence I think it's *O(n^2)*.

In the memoized function, more than half of the values are accessed based on memoization. I've read that *an algorithm is O(log N) if it takes constant time to reduce the problem space by a fraction* and that *an algorithm is O(N) if it takes constant time to reduce the problem space by a constant amount*. Am I right in believing that the memoized implementation is *O(n)* in complexity? If so, wouldn't the iterative implementation be the best among all three? (as it does not use the additional memory that memoization requires).