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Computational complexity of Fibonacci Sequence

Hi, I found out a inductive proof yesterday for the time complexity of a recursive Fibonacci program.The proof first claimed that the complexity is exponential(and later goes on to prove it by induction) by saying that:

There exists a "r" such that f(n) >= r^n for all r>=1 and n>=1.

Then it chooses r to be equal to 1+sqrt(5)/2 such that it satisfies the equation r^2 = r + 1.

(It later justifies it's choice for r).

And then it says that now the statement becomes f(n) >= r^(n-2).

I didn't understand this part how does it become r^(n-2) from r^n.Can someone please help me with that.

marked as duplicate by Brian Roach, Mehrdad, Drew Noakes, user85109, Graviton May 3 '11 at 13:47

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As Daniel says, r is greater than 1 so r^n is greater than r^(n-1) which is greater than r^(n-2) etc...

So you have indeed: f(n) >= r^n >= r^(n-1) >= r^(n-2)

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  • f(n) >= r^n
  • r * r * f(n) >= r^n (since r > 1)
  • f(n) >= r^(n-2)

I don't see how this relates to time complexity, though..? It sounds more like a discussion leading up to Binet's formula.

  • It shows that f(n) is Ω(r^n) by showing that f(n) >= r^n for some r and sufficiently large n. – hammar May 3 '11 at 7:06
  • I didn't get you . – station May 3 '11 at 7:07
  • @hammer I see, it just seems like a funny approach. In my mind, the natural argument is this: f(n) = 2*f(n-2) is trivially exponential (given f(1) = 1) since it doubles every two steps, and f(n-1) + f(n-2) > 2*f(n-2) since f increases monotonically, hence f(n) = f(n-1) + f(n-2) is also exponential. Isn't that simpler? :-) – Daniel Lubarov May 3 '11 at 7:52
  • Yes, I agree it is a somewhat convoluted approach. – hammar May 3 '11 at 10:32

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