Wikipedia:Reference desk/Archives/Mathematics/2023 February 1
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February 1
[edit]How many non-equal pairing schemes?
[edit]Imagine 2 identical sets of unique items (eg "a,b,c,d" "a,b,c,d"). How many different pairing schemes are there when no pair comprises identical items? With n=1 ("a" "a") it is 0 as the only pair is "aa". With n=2 ("a,b" "a,b") it is 1 (ab,ab). With n=3 ("a,b,c" "a,b,c") it is 1 (ab,ac,bc) and with n=4 ("a,b,c,d" "a,b,c,d") it is 6 (ab,ab,cd,cd) (ab,ac,bd,cd) (ab,ad,bc,cd) (ac,ac,bd,bd) (ac,ad,bc,bd) and (ad,ad,bc,bc). Is there a formula for this? -- SGBailey (talk) 11:23, 1 February 2023 (UTC)
- This sounds like the number of Derangements, except you're counting a permutation and its inverse as the same thing. So off the top of my head it's (number of derangement + number of derangements of order 2)/2. The number of derangement of order 2 should be straightforward, 0 if n is odd and (n-1)(n-3)...(3)(1) if n is even. Another way to look at this is the number of Multigraphs (no loops) on n nodes with degree 2. --RDBury (talk) 14:38, 1 February 2023 (UTC)
- With even n some derangements are self-inverse, so dividing by 2 gives an undercount. —Tamfang (talk) 18:24, 1 February 2023 (UTC)
- It's more than just identifying a permutation with its inverse. Consider n=6, and a permutation consisting of two disjoint 3-cycles. Each 3-cycle is being identified with its inverse, which means 4 different permutations are being collapsed into 1.--2600:4040:7B33:6E00:7D1B:6AA6:5446:FA6B (talk) 18:32, 1 February 2023 (UTC)
- This is sequence A002137 in the OEIS (see the last comment by Kellen Myers). --Lambiam 18:49, 1 February 2023 (UTC)
- I think it will satisfy this recurrence relation: . Here (n-1)!/2 counts the pairings coming from a single n-cycle, and otherwise you have an i-cycle containing the first element, and an (n-i)-pairing for the remaining elements.2600:4040:7B33:6E00:7D1B:6AA6:5446:FA6B (talk) 18:54, 1 February 2023 (UTC)
- Taking this formula results in --Lambiam 19:41, 1 February 2023 (UTC)
- Right, it shouldn't be dividing by 2 for 2-cycles.2600:4040:7B33:6E00:7D1B:6AA6:5446:FA6B (talk) 20:20, 1 February 2023 (UTC)
- Here is the corrected relation. Putting we have, for
- Defining we obtain a simpler (but no longer integer-valued) recurrence relation:
- Further defining produces, for
- Next, using brings us back to integer terrain, with
- Then (This can probably be done in fewer steps.) --Lambiam 23:46, 1 February 2023 (UTC)
- This is sequence A345132 in the OEIS. --Lambiam 09:20, 2 February 2023 (UTC)
- I take the point about my formula being wrong with n=6. I'm pretty sure it's right for n<=5 though, so it's not undercounting anything, just overcounting ones with multiple cycles of length >2. For example for n=2, 3, 4 it gives (1+1)/2 = 1, (2+0)/2 = 1, (9+3)/2 = 6. For the correct formula, the OEIS gives the exponential generating function and it should be possible to generate a recursion from that in addition to deriving it independently; that kind of thing is usually included in the OEIS and I assume that whoever was working on the entry figured the e.g.f. was enough. I have a feeling that if there were a simple closed form expression the the OEIS would have it. --RDBury (talk) 23:58, 1 February 2023 (UTC)
- Here is the corrected relation. Putting we have, for
- Right, it shouldn't be dividing by 2 for 2-cycles.2600:4040:7B33:6E00:7D1B:6AA6:5446:FA6B (talk) 20:20, 1 February 2023 (UTC)
- Taking this formula results in --Lambiam 19:41, 1 February 2023 (UTC)
Thank you all - this is far more complicated than I expected. -- SGBailey (talk) 06:44, 2 February 2023 (UTC)