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What is the BigOh complexity of the binary search if each split was 1/3 to 2/3 instead of 1/2 to 1/2? Some explanation of how the BigOh complexity is derived would be helpful too. Thanks

This question comes up in the "Algorithm Design Manual" by Steven Skiena.

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closed as off topic by Jim Lewis, JE SUIS CHARLIE, Bhavin, Shahrooz, Neil Jun 10 '13 at 12:34

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Is this a homework question, or just for your own personal reading? If the former, you may want to add the [homework] tag to your question. –  CosmicComputer Jun 9 '13 at 2:43
No its not my homework question. Its my personal reading. Steven Skiena has given the answer in the book but I did not get the reasoning behind it –  Pertinent Observer Jun 9 '13 at 2:51
Are you familiar with the master theorem? –  SheetJS Jun 9 '13 at 3:05
@nirk yes, I am familiar with master theorem. As per link the complexity will be logn. In the book, the author suggests log (3/2) n. ie. base is 3/2. I was curious, as to how the 3/2 was arrived at. –  Pertinent Observer Jun 9 '13 at 12:28

2 Answers 2

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So in your question the sorted array is divided into two with size 1/3 and 2/3. Let us assume in the worst case you are always searching the sub array having 2/3 elements. In that case the recurrence relation is as follows,

T(n) = T(2n/3) + c

After each comparison you can remove 1/3rd of the elements from further checking. Thus we get the above recurrence relation.

Solving this recurrence relation using Master's Theorem with a=1 and b=3/2, f(n)=Θ(1). We get the second case of Master theorem with f(n) = Θ(nlogb a), then T(n) = Θ(nlogb a logb n).

Thus we get T(n)=Θ(n0 logb n).

In this particular case, we have T(n) = Θ(log3/2 n)

But remember in complexity theory the base of the logarithm is immaterial as the base of a logarithm can be changed by a constant multiplication. Constants can be removed while analyzing complexity without any loss of generality.

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thanks. This helps. The wikipedia entry appears to have the incorrect T(n) formula for this case –  Pertinent Observer Jun 10 '13 at 13:42

The big-O complexity of binary search assumes a pre-sorted array, so bear in mind that while the search itself may be of a certain big-O complexity, it will take longer if your data is not already sorted.

For the case of a binary search, the complexity O(logN) is derived from the fact that if you have 2^m elements, you will split your data m times (halving the remainder to search each time until you arrive at only one element). The operation that takes us from N = 2^m elements to m steps is the logarithm (base 2); log(base 2)N = log(base 2)2^m = m. We ignore the fact that the base of the logarithm is 2 rather than 10 or e, because that just introduces a constant factor: log(N)/log(2) = log(base 2)N, and we're interested in the degree of growth, not the coefficients.

As for the 1/3 to 2/3 split case, that should be of the same complexity. Just as with an actual binary search, you are reducing the number of elements you have to search geometrically each time - although instead of halving them, you're multiplying them by 1/3 or 2/3. This should change the base of your logarithm - and you will have different bases for best, worse, and average case scenarios - but again, we don't care about that for big-O notation.

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