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My friend Rasna posed this question to me; felt like sharing it here.

Given a deck of cards, we split it into 2 groups, and "interleave them"; let us call this operation a 'split-join'. And repeat the same operation on the resulting deck.

E.g., { 1, 2, 3, 4 } becomes { 1, 2 } & { 3, 4 } (split) and we get { 1, 3, 2, 4 } (join)

Also, if we have an odd number of cards i.e., { 1, 2, 3 } we can split it like { 1, 2 } & { 3 } (bigger-half first) leading to { 1, 3, 2 } (i.e., n is split up as Ceil[n/2] & n-Ceil[n/2])

The question she asked me was:

HOW many such split-joins are needed to get the original deck back?

And that got me wondering:

If the deck has n cards, what is the number of split-joins needed if:

  • n is even ?
  • n is odd ?
  • n is a power of '2' ? [I found that we then need log (n) (base 2) number of split-joins...]
  • (Feel free to explore different scenarios like that.)

Is there a simple pattern/formula/concept correlating n and the number of split-joins required?

I believe, this is a good thing to explore in Mathematica, especially, since it provides the Riffle[] method.

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3  
How do your split your deck when there is an odd number of items? –  Benoit Jan 9 '12 at 12:33
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Please write proper English and don't litter your questions with unusual contractions, emoticons and converting all your "and"s to ampersands. We expect a professional tone here. –  BoltClock Jan 9 '12 at 12:46
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@Benoit -- Have added 1 strategy in the question, but feel free to assume the opposite too, if you can find more interesting things. –  fritz Jan 9 '12 at 13:29

3 Answers 3

To quote MathWorld:

The numbers of out-shuffles needed to return a deck of n=2, 4, ... to its original order are 1, 2, 4, 3, 6, 10, 12, 4, 8, 18, 6, 11, ... (Sloane's A002326), which is simply the multiplicative order of 2 (mod n-1). For example, a deck of 52 cards therefore is returned to its original state after eight out-shuffles, since 2**8=1 (mod 51) (Golomb 1961). The smallest numbers of cards 2n that require 1, 2, 3, ... out-shuffles to return to the deck's original state are 1, 2, 4, 3, 16, 5, 64, 9, 37, 6, ... (Sloane's A114894).

The case when n is odd isn't addressed.

Note that the article also includes a Mathematica notebook with functions to explore out-shuffles.

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thanks a lot for these pointers. Will explore for different cases and see if i find something interesting. –  fritz Jan 9 '12 at 14:02

If we have an odd number of cards n==2m-1, and if we split the cards such that during each shuffle the first group contains m cards, the second group m-1 cards, and the groups are joined such that no two cards of the same group end up next to each other, then the number of shuffles needed is equal to MultiplicativeOrder[2, n].

To show this, we note that after one shuffle the card which was at position k has moved to position 2k for 0<=k<m and to 2k-2m+1 for m<=k<2m-1, where k is such that 0<=k<2m-1. Written modulo n==2m-1 this means that the new position is Mod[2k, n] for all 0<=k<n. Therefore, for each card to return to its original position we need N shuffles where N is such that Mod[2^N k, n]==Mod[k, n] for all 0<=k<n from which is follows that N is any multiple of MultiplicativeOrder[2, n].

Note that due to symmetry the result would have been exactly the same if we had split the deck the other way around, i.e. the first group always contains m-1 cards and the second group m cards. I don't know what would happen if you alternate, i.e. for odd shuffles the first group contains m cards, and for even shuffles m-1 cards.

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that's beautiful (symmetry, I did feel it should not make a difference, but sometimes intuition can go wrong!)...have some other special cases in my mind...let me see...! Thanks a lot indeed... –  fritz Jan 10 '12 at 14:54

There's old work by magician/mathematician Persi Diaconnis about restoring the order with perfect riffle shuffles. Ian Stewart wrote about that work in one of his 1998 Scientific American Mathematical Recreation columns -- see, e.g.: http://www.whydomath.org/Reading_Room_Material/ian_stewart/shuffle/shuffle.html

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Wow...! That's very informative and nice...! Thanks :) –  fritz Jan 10 '12 at 14:55

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