My friend 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

suchsplit-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.