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This is about analysis of algorithms: Say, the running time of a problem is:

T(n) = { 1, for n == 1 | T(n/3) + THETA(1), for n > 1}

Now, this is THETA(log base3 n)

But, if I use Master Method, I evaluate to THETA(log base2 n), using Case II

How am I supposed to get the correct answer from master method?

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THETA(log base3 n) is equal to THETA(log base2 n) –  fgb Oct 17 '12 at 3:27
How is that possible? An algorithm dividing problem into one-third of the original problem is faster that the one dividing into half. So, THETA(log base2 n) is slower that THETA(log base3 n). –  Flipper Oct 17 '12 at 3:30
@jaskirat: Yes, but only by a constant factor. THETA doesn't care about those. –  hammar Oct 17 '12 at 3:34
Okay, so for big enough n, THETA(log base3 n) boils down to THETA(log base2 n). Is this right? –  Flipper Oct 17 '12 at 3:37
Not just for big enough n. For all n, log base 3 n = k * (log base 2 n) where k = 1 / log base 2 3 which is constant with respect to n. –  hammar Oct 17 '12 at 3:41

1 Answer 1

up vote 1 down vote accepted

They're the same. For any two bases a and b, Θ(loga n) = Θ(logb n), so we usually don't mention the base at all and just say Θ(log n).

This is because loga n = (1 / logb a) * logb n, so they differ by a factor of 1 / logb a which is constant with respect to n.

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But we do use bases in Big-oh, right? So, Big-oh(log base2 n) is different from Big-oh(log base3 n)? –  Flipper Oct 17 '12 at 3:58
The same argument works for O(log n). It's still a constant factor and those disappear with Big-O as well. –  hammar Oct 17 '12 at 4:01

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