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Am trying to solve the given recursion, using recursion tree, T(n) = 3T(n/3) + n/lg n.

In the first level (n/3)/(log(n/3)) + (n/3)/(log(n/3)) + (n/3)/(log(n/3)) = n/(log(n/3)).

In the second level it turns out to be n/(log(n/9)).

Can I generalize the above equation in the form of n.loglogn

This is a general doubt I've, I need an insight on this.

Note: Any function that has to be Theta(n^k log^k (n)) in that function k should >=1. And in this case k is -1 so master theorem doesn't come in to picture

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Is this your homework? –  TFD Feb 10 '10 at 4:47
Does not seem so, to me. –  Aryabhatta Feb 10 '10 at 4:50
Are you looking for the (closed-form) solution, or to find the computational complexity? –  BlueRaja - Danny Pflughoeft Feb 11 '10 at 1:22

1 Answer 1

up vote 6 down vote accepted

It is true, the Master theorem does not apply.

T(n) = 3T(n/3) + n/logn.

Let g(n) = T(n)/n.

Then n*g(n) = 3*(n/3)*g(n/3) + n/logn.


g(n) = g(n/3) + 1/log n.

This gives g(n) = Sum 1/log n + 1/log n/3 + 1/log n/9 + ...

= Theta(Sum 1/logn + 1/(logn -1) + 1/(log n - 2) + ...) = Theta(Integral 1/x between 1 and logn) = Theta(log log n).

Thus T(n) = n*g(n) = Theta(n*log logn.)

You guessed it right.

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Seems like there is an error right at the step between where you introduce g(n)=T(n)/n and the n*g(n)=... part; n/logn never went up to n^2/logn –  Adam Miller Sep 12 '13 at 5:56

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