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I want to prove the following statement

2^(⌊lg n⌋+⌈lg n⌉)∕n ∈ Θ(n)

I know that to prove it, we have to find the constants c1>0, c2>0, and n0>0 such that

c1.g(n) <= f(n) <= c2.g(n) for all n >= n0

In other words, we have to prove f(n) <= c.g(n) and f(n) >= c.g(n).

The problem is how to prove the left hand side (2^(⌊lg n⌋+⌈lg n⌉)∕n)

Thank you

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Is this question inspired by a homework assignment? If so, please add the [homework] tag. – Heath Hunnicutt Jan 16 '12 at 23:42
    
What do you mean by proving a statement> Only theorems have proof, what theorem is that? – Senthil Kumaran Jan 16 '12 at 23:43

You can start by expanding the exponential. It is equal to n1*n2/n, where n1<=n<=n2, 2*n1>n and n*2>n2. The rest should be easy.

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could you please give me more explanation about how to expand ⌊lg n⌋+⌈lg n⌉ ? – Nasser Jan 17 '12 at 0:47
    
@MR.NASS Dont expand logs, instead expand the exponentials. Here n1 and n2 are the upper and lower limits on n. – ElKamina Jan 17 '12 at 4:59

Here's a derivation for the upper bound:

2^(⌊lg n⌋+⌈lg n⌉)/n
= 2^(2⌊lg n⌋+1)/n 
<= 2^(2 lg n + 1)/n
= 2^(2 lg n) 2^(1) / n
= 2 n^2 / n
= 2 n
= O(n)

So we know your function can be bounded above by 2*n. Now we do the lower bound:

2^(⌊lg n⌋+⌈lg n⌉)/n
= 2^(2⌈lg n⌉ - 1) / n
>= 2^(2 lg n - 1)/n
= 2^(2 lg n) 2^(-1) / n
= 1/2 n^2 / n
= 1/2 n
= O(n)

We now know that your function can be bounded below by n/2.

Checked on gnuplot; these answers look good and tight. This is a purely algebraic solution using the definition if floor() and ceiling() functions.

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