**This is not the actual answer to the question, just an approach to generate the whole sequence in **`O(n)`

Provided you mean `O(log(n))`

time complexity to calculate just the n'th element, not all up to `n`

it is actually quite easy. If you iterate through, you can easily do `O(1)`

for each element with proper memoization.

I'll suppose this:

```
a[1] = 1, a[2] = 1, fib[1] = 0, fib[2] = 1, fib[3] = 1
```

Then just iterate and memorize `a[n-1]`

and `a[n-2]`

as well as `fib[n-1]`

and `fib[n-2]`

along the way:

```
long an_1 = 1; // a[2]
long an_2 = 1; // a[1]
long fib_1 = 2; // fib[4]
long fib_2 = 1; // fib[3]
// Starts with a[3]
while (true)
{
long fib = fib_1 + fib_2;
long an = an_1 + an_2 + fib;
std::cout << an;
fib_2 = fib_1;
fib_1 = fib;
an_2 = an_1;
an_1 = an;
}
```

**Edit**: this is called amortized complexity. Computing up to the `n`

-th element requires `O(n)`

steps, but as you have all elements from `1`

to `n`

available when you reach this point the cost of computing each element is `O(1)`

. The formal proof is a bit more elaborated but this is the idea.

`O(n)`

numbers in`O(log(n))`

. If you just need the nth Number look at wikipedia for a direct calculation formula. – Grizzly Sep 3 '12 at 18:37