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1,4,13,40,121...((3 * n) + 1) works slightly more efficiently than 1,2,4,8,16...(2 * n) when inserting random numbers to a sorting algorithm.

Why is this? Is it anything to do with threading?


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Is this a homework question? – GWW Mar 30 '11 at 3:29
I dont think it has anything to do with threading, but +1 to know answers, interesting. – Sanjeevakumar Hiremath Mar 30 '11 at 3:31
Curious research extended from homework, so in a way yes. – kymully Mar 30 '11 at 3:31
What does mean "slightly more efficiently"? – xappymah Mar 30 '11 at 3:34
Are you, perhaps, talking about the step sizes in a Shell sort, rather than a pure insertion sort? – Jerry Coffin Mar 30 '11 at 3:42

It is well known that the shell sort increment steps of 2^k, 2^(k-1), ..., 1 are one of the worst. For instance, you only compare the elements at the odd positions, with the ones at the even positions only at the last step!

The other steps seem to be (3^k -1)/2 (and not 3n+1) and don't suffer from problems like the even/odd issue. That is not a proof, but we might expect this to be better than powers of 2.

If you are looking for mathematical analysis, Shell Sort is well known for giving mathematicians a hard time.

I didn't find any analysis of your sequence in Sedgewick's paper here. Perhap one of Knuth's books has it.

Good luck.

btw, why do you ask about threading?

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@Moron: (@kymully:) he writes 2*n and 3*n+1 but he means a(n+1)=2*a(n) and a(n+1)=3*a(n)+1. – ypercubeᵀᴹ Mar 30 '11 at 13:36

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