# Computational complexity of Fibonacci Sequence

I understand Big-O notation, but I don't know how to calculate it for many functions. In particular, I've been trying to figure out the computational complexity of the naive version of the Fibonacci sequence:

``````int Fibonacci(int n)
{
if (n <= 1)
return n;
else
return Fibonacci(n - 1) + Fibonacci(n - 2);
}
``````

What is the computational complexity of the Fibonacci sequence and how is it calculated?

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Good answers here. –  Greg Dec 11 '08 at 20:26
See the matrix form section here: en.wikipedia.org/wiki/Fibonacci_number . by doing this matrix ^ n (in a clever way) you can compute Fib(n) in O(lg n). The trick is in doing the power function. Theres a very good lecture on iTunesU about this exact problem and how to solve in O(lg n). The course is intro to algorithms from MIT lecture 3 (its absolutley free so check it out if you're interested) –  Aly Feb 11 '11 at 16:50

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``)`

However, as noted in a comment, this is not the tight bound. An interesting fact about this function is that the T(n) is asymptotically the same as the value of `Fib(n)` since both are defined as

`f(n) = f(n-1) + f(n-2)`.

The leaves of the recursion tree will always return 1. The value of `Fib(n)` is sum of all values returned by the leaves in the recursion tree which is equal to the count of leaves. Since each leaf will take O(1) to compute, `T(n)` is equal to `Fib(n) x O(1)`. Consequently, the tight bound for this function is the Fibonacci sequence itself (~`θ(1.6``n``)`). You can find out this tight bound by using generating functions as I'd mentioned above.

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Also Proof by induction. Nice. +1 –  Andrew Rollings Dec 11 '08 at 20:38
Although the bound is not tight. –  Captain Segfault Dec 11 '08 at 21:15
@Captain Segfault: Yeah. I clarified the answer. You'd get the tight bound using GF method as I had written above. –  LeakyCode Dec 11 '08 at 21:36
Itake your StackOverflowException as a joke. The exponential time is perceivable quite easily with rather small values for n. –  David Rodríguez - dribeas Dec 11 '08 at 23:08

Just ask yourself how many statements need to execute for `F(n)` to complete.

For `F(1)`, the answer is `1` (the first part of the conditional).

For `F(n)`, the answer is `F(n-1) + F(n-2)`.

So what function satisfies these rules? Try a^n:

``````a^n == a^(n-1) + a^(n-2)
``````

Divide through by `a^(n-2)`:

``````a^2 == a + 1
``````

Solve for `a` and you get `(1+sqrt(5))/2`, otherwise known as the golden ratio.

So it takes exponential time.

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Proof by induction. Nice. +1 –  Andrew Rollings Dec 11 '08 at 20:37
30 upvotes for a wrong answer? :-) Does it follow that 1=F(1)=(1+sqrt(5))/2 ? And what about the other solution, (1-sqrt(5))/2? –  Carsten Schultz Aug 24 '13 at 22:11

It is bounded on the lower end by `2^(n/2)` and on the upper end by 2^n (as noted in other comments). And an interesting fact of that recursive implementation is that it has a tight asymptotic bound of Fib(n) itself. These facts can be summarized:

``````T(n) = Ω(2^(n/2))  (lower bound)
T(n) = O(2^n)   (upper bound)
T(n) = Θ(Fib(n)) (tight bound)
``````

The tight bound can be reduced further using its closed form if you like.

-

There's a very nice discussion of this specific problem over at MIT. On page 5, they make the point that, if you assume that an addition takes one computational unit, the time required to compute Fib(N) is very closely related to the result of Fib(N).

As a result, you can skip directly to the very close approximation of the Fibonacci series:

``````Fib(N) = (1/sqrt(5)) * 1.618^(N+1) (approximately)
``````

and say, therefore, that the worst case performance of the naive algorithm is

``````O((1/sqrt(5)) * 1.618^(N+1)) = O(1.618^(N+1))
``````

PS: There is a discussion of the closed form expression of the Nth Fibonacci number over at Wikipedia if you'd like more information.

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Nice reference to the MIT stuff. –  Charlie Martin Dec 13 '08 at 1:38

This performs way better:

``````unsigned int Fib(unsigned int n)
{
// first Fibonaci number is Fib(0)
// second one is Fib(1) and so on

// unsigned int m;  // m + current_n = original_n
unsigned int a = 1; // Fib(m)
unsigned int b = 0; // Fib(m-1)
unsigned int c = 0; // Fib(m-2)

while (n--)
{
c = b;
b = a;
a = b+c;
}

return a;
}
``````
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That doesn't explain how to calculate big O notation for the function. –  Matt Ellen Apr 28 '10 at 20:43
@Matt Ellen: It's simple. This function is `O(n)`, since the number of iterations of the `while` loop is equal to `n`, and there is no other loop or recursive call. (Proving `6*n + 4` is `O(n)` is trivial if you know the definition of the `O` notation.) –  Eduardo León Apr 29 '10 at 2:52
Determining Big-O is entirely academic, unless you have an alternative implementation (and Big-O) to compare it to. Eduardo supplies the counterpoint here. –  Jason Jul 26 '10 at 18:38
I agree that this can be a much better way of implementing it, but the notion of Big-O comments on the algorithm used for a problem. For instance, the expected runtime of bogosort (en.wikipedia.org/wiki/Bogosort) is `O(2^n)`, but there are other ways to sort a list more efficiently (for instance selection sort). I think Juliet is asking about the order of the algorithm she provided, which she calls the "naive version." –  Oliver Sep 30 '10 at 21:05
@starghost: Agreed. Since her algorithm just adds 1s, the order of her algorithm is `O(Fib(n))` itself. –  Eduardo León Oct 1 '10 at 3:06

Problem 16.8 gives the outline for a really cool solution using linear algebra.

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Well, according to me to it is `O(2^n)` as in this function only recursion is taking the considerable time (divide and conquer). We see that, the above function will continue in a tree until the leaves are approaches when we reach to the level `F(n-(n-1))` i.e. `F(1)`. So, here when we jot down the time complexity encountered at each depth of tree, the summation series is:

``````1+2+4+.......(n-1)
= 1((2^n)-1)/(2-1)
=2^n -1
``````

that is order of `2^n [ O(2^n) ]`.

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The proof answers are good, but I always have to do a few iterations by hand to really convince myself. So I drew out a small calling tree on my whiteboard, and started counting the nodes. I split my counts out into total nodes, leaf nodes, and interior nodes. Here's what I got:

``````IN | OUT | TOT | LEAF | INT
1 |   1 |   1 |   1  |   0
2 |   1 |   1 |   1  |   0
3 |   2 |   3 |   2  |   1
4 |   3 |   5 |   3  |   2
5 |   5 |   9 |   5  |   4
6 |   8 |  15 |   8  |   7
7 |  13 |  25 |  13  |  12
8 |  21 |  41 |  21  |  20
9 |  34 |  67 |  34  |  33
10 |  55 | 109 |  55  |  54
``````

What immediately leaps out is that the number of leaf nodes is `fib(n)`. What took a few more iterations to notice is that the number of interior nodes is `fib(n) - 1`. Therefore the total number of nodes is `2 * fib(n) - 1`.

Since you drop the coefficients when classifying computational complexity, the final answer is `θ(fib(n))`.

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(No, I didn't draw a full 10-deep call tree on my whiteboard. Just 5-deep.) ;) –  benkc Feb 28 at 1:23