# analysis of fibonacci algorithm

I am reading an analysis of a fibanocci number program, shown below. It is mentioned that this implementation is inefficient. Indeed, the number of recursive calls to compute Fn is F(n+1).

My question is: what does "the number of recursive calls to compute Fn is F(n+1)" mean?

``````int F(int i)
{
if (i < 1) return 0;
if (i == 1) return 1;
return F(i-1) + F(i-2);
}
``````
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The naive implementation to compute fibonacci numbers takes F(n+1) recursive calls to compute the number F(n); i.e. to compute f(10)=55 you need 89 recursive calls, and 89 is F(11).

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"complexity of program is approximately equal to bigoh(2power(n)) . Since O(n) < O(2powerN) recursive method is not efficient. "

If they compute this complexity in terms of the amount of recursive calls needed, then I don't know where they get 2^n. The graph doesn't model 2^n at all, for larger values the modeling decays significantly. By the 30th term of 832,040, it takes 2,692,536 recursive calls to compute it, far less than 2^30 which is over 1 billion. It's less than 1%!

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If we want to compute Nth Fibonacci number F(n)=F(n-1)+F(n-2) .We can do it with iteration method and recursive method. if we do it with iterative method

``````#include<stdio.h>

main()
{
int a=0,b=1,c,i,n;
//clrscr();
printf("enter the limit of series\n");
scanf("%d",&n);
if(n==0)
printf("%d\n",a);
else
printf("%d\n%d\n",a,b);
for(i=2;i<=n;i++)
{
c=a+b;
printf("%d\n",c);
a=b;
b=c;
}

}
``````

It takes O(n) time as it iterates from i=0 to N.

But with recursive method

``````int F(int i)
{
if (i < 1) return 0;
if (i == 1) return 1;
return F(i-1) + F(i-2);
}
``````

The recurrence relation is

``````                     ___________ 0 if(n<=0)
/___________ 1 if(n==1)
Fibonacci(n) ____/
\
\___________ Fibonacci(n-1)+Fibonacci(n-2)
``````

So our problem for n = sub-problem of (n-1) + sub-problem of (n-2) hence our time function T(n) is as follows

``````   T(n)=T(n-1)+T(n-2)+O(1)
T(n)={T(N-2)+T(n-3)}+T(n-2)  since T(n-1)=T(n-2)+T(n-3) -------- equation(1)
from above you can see T(n-2) is calculated twice. If we expand the recursion tree for N=5 . The recursion tree is as follows

Fib(5)
|
_____________________/ \__________________
|                                          |
Fib(4)                   +                 fib(3)
|                                          |
_______/ \_______                         ________/ \_______
|        +        |                        |        +        |
Fib(3)             Fib(2)                   Fib(2)           Fib(1)
|                  |                        |
_______/ \____        ____/ \_______        _______/ \_____
|        +     |      |     +        |      |         +      |
Fib(2)        Fib(1)    Fib(1)      Fib(0)     Fib(1)        Fib(0)
_______/ \_______
|        +        |
Fib(1)             Fib(0)
``````

If we observe the recurrsion tree we find that Fib(1) is caliculated 5 times Fib(2) is caliculated 3 times Fib(3) is caliculated 2 times

So using recursion we are actually doing redundant computations . If you use iterative method these redudant calculations are avoided.

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

From previous SO post Computational complexity of Fibonacci Sequence

complexity of program is approximately equal to bigoh(2power(n)) . Since O(n) < O(2powerN) recursive method is not efficient.

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Epic ASCII tree –  Mike T Sep 13 '12 at 8:14

It means that to calculate the Fibonacci number of 10 numbers you need to run the recursion 10+1 times to obtain it. There are various algorithm that could improve this timeline.

Look at this post here which explains the time complexity of finding Fibonacci numbers and their improvement: Computational complexity of Fibonacci Sequence

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F(n+1), not F(n)+1. –  chepner Sep 12 '12 at 16:03
@chepner true, but that was not my point. I replied directly to what the question asked, which is F(n+1) and i just referred to n :) –  Steven Sep 12 '12 at 16:57

Here is my algo for fibonacci

``````#include<stdio.h>

main()
{
int a=-1,b=1,c,i,n;
printf("enter the limit of series\n");
scanf("%d",&n);
for(i=1;i<=n;i++)
{
c=a+b;
printf("%d\n",c);
a=b;
b=c;
}
}
``````
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