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I am trying to find the time complexity for the recurrence:

T(n) = 2T(n1/2) + log n

I am pretty close to the solution, however, I have run into a roadblock. I need to solve:

n(1/2k) = 1

for k to simplify my substitution pattern. I am not looking for answers to the recurrence, just a solution for k.

Any help would be appreciated. Thanks!

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I don't think that would help. If you solve that for k you get something positively frightening. – harold Oct 27 '12 at 20:39

3 Answers 3

It's impossible to solve

n(1/2k) = 1

for k, since if n > 1 then nx > 1 for any nonzero x. The only way that you could solve this is if you picked k such that 1 / 2k = 0, but that's impossible.

However, you can solve this:

n(1/2k) = 2

First, take the log of both sides:

(1 / 2k) lg n = lg 2 = 1

Next, multiply both sides by 2k:

lg n = 2k

Finally, take the log one more time:

lg lg n = k

Therefore, this recurrence will stop once k = lg lg n.

Although you only asked for the value of k, since it's been a full year since you asked, I thought I'd point out that you can do a variable substitution to solve this problem. Try setting k = 2n. Then k = lg n, so your recurrence is

T(k) = 2T(k / 2) + k

This solves (using the Master Theorem) to T(k) = Θ(k log k), and using the fact that k = lg n, the overall recurrence solves to Θ(log n log log n).

Hope this helps!

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log base anything of 1, is 0.


n^((1/2)^k) = 1

log(n)(n^((1/2)^k)) = log(n)(1)

1/2^k = 0

log(1/2)((1/2)^k) = log(1/2)(0)

log base anything of 0 is negative infinity.. so...

k = -infinity.

I think you should use a different "final number" for n, than 1 just saying...

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mainly because you'll never be able to continue square rooting until 1. You'll go insane. – Serge Oct 27 '12 at 20:54

dude if it were quick sort that was the equation:

enter image description here

The solution for this is O(n*log(n)) since now it is even smaller(T(n) ~ n^1/2) for some N it means your complexity is less than O(n*log(n)).

Try to use induction to prove your bound

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Yeah, I agree it would be, as the combine is sub linear, and the input size is much smaller as well. However, if all else fails, I will try induction, but I am just curious in general how I might solve equations of the form c^a^b = 1 for b. I know it involves some trickery using power identities. – Waqas Oct 27 '12 at 20:42
try with log functions... – 0x90 Oct 28 '12 at 7:51

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