# Proving Fibonacci recursive algorithm time complexity

I am trying to understand a proof by induction in my algorithms text book. Here's the author is proving using induction that the T(n) will always be greater than 2^(n/2) (This is for calculating the nth fibonacci number using the recursive algorithm):

What I don't understand is the very last step, where he is manipulating the equation. How does he go from:

``````> 2^(n-1)/2 + 2^(n-2)/2 +1
``````

to

``````> 2^(n-2)/2 + 2^(n-2)/2 +1
``````

He just randomly changes `2^(n-1)/2` to `2^(n-2)/2`. Is this a mistake?

Thanks.

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I believe that particular step runs off the assumption that:

``````T(n-1) > T(n-2)
``````

Therefore, we can form an algebraic inequality:

``````T(n-1) + T(n-2) + 1 > T(n-2) + T(n-2) + 1
``````

We can lop off the + 1 from the right side (because the inequality will still hold true for anything subtracted away on the LESSER side):

``````T(n-1) + T(n-2) + 1 > T(n-2) + T(n-2)
``````

From this, substitute our T(m) = 2^(m/2) (for anything less than n and > 2, which n-1 and n-2 both qualify):

``````2^(n-1)/2 + 2^(n-2)/2 + 1 > 2^(n-2)/2 + 2^(n-2)/2
``````

That gets you that particular step. It's done this way deliberately as the poster above me stated, to get to 2^(n/2).

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Ah...thanks. Much clear. –  0xSina Sep 30 '11 at 9:03

It's deliberate, if you look closely it's an inequation and he uses it do finish the induction step.

Note the typo, it should say "We must show that T(n) > 2^(n/2)" and not <.

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