I implemented the shuffling algorithm as:

import random
a = range(1, n+1) #a containing element from 1 to n
for i in range(n):
    j = random.randint(0, n-1)
    a[i], a[j] = a[j], a[i]

As this algorithm is biased. I just wanted to know for any n(n ≤ 17), is it possible to find that which permutation have the highest probablity of occuring and which permutation have least probablity out of all possible n! permutations. If yes then what is that permutation??

For example n=3:

a = [1,2,3]

There are 3^3 = 27 possible shuffle

No. occurence of different permutations:

1 2 3 = 4

3 1 2 = 4

3 2 1 = 4

1 3 2 = 5

2 1 3 = 5

2 3 1 = 5

P.S. I am not so good with maths.

  • this is not correct python syntax – dangee1705 Sep 11 at 9:13
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    I just have one very quick question how you get combination possible is 27, because if we go with basic permutation algo. possible combination for 3 values will go to 6, with factorial calculation. – Simmant Sep 11 at 10:49
  • @Simmant 27 is the total number of different swaps which can be done for a list of length 3. For any i, j can be (0 to n-1), even i (in which case there will be no swap) – gc7 Sep 11 at 12:14
  • and the link given by @squeamishossifrage tells that it is possible to know which permutation has the least probability and can be calculated by looking at all the possibilities the random function goes and reaches the final permutation. – gc7 Sep 11 at 12:25

This is not a proof by any means, but you can quickly come up with the distribution of placement probabilities by running the biased algorithm a million times. It will look like this picture from wikipedia:

permute with all order bias

An unbiased distribution would have 14.3% in every field.

To get the most likely distribution, I think it's safe to just pick the highest percentage for each index. This means it's most likely that the entire array is moved down by one and the first element will become the last.

Edit: I ran some simulations and this result is most likely wrong. I'll leave this answer up until I can come up with something better.

  • But that exactly is my problem. For n > 7, i can't run the program as to get an accurate answer in feasible time. So, is there any efficient way of doing this(for n=9 i have to run the program at least 9^9 times, to get anyway near to theaccurate result). – tanweer anwar Sep 11 at 12:58
  • You can use a Markov Chain algorithm to derive the probability by position chart like the one in Wikipedia; that would take O(n³) multiplications so it's practical for n=17. But the occupancy of different positions might not be independent of each other, so just taking the highest probability for each index might not be correct. Although I think it is, I don't have a proof. – rici Sep 11 at 13:54
  • @rici can you explain how to implement Markov Chain Algorithm for this particular problem... – tanweer anwar Sep 11 at 14:09
  • Actually, I was wrong. The highest probability permutation is not the one with the highest probability for each index. So the Wikipedia-style chart doesn't actually help you. Still, it would be a good way to learn about Markov Chains, if that is the intent of the course you are taking. – rici Sep 11 at 14:40
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    @fafl: if I didn't make a mistake with a quick MC implementation over all permutations, the top two permutations for n=7 (the Wikipedia diagram) are (1, 2, 3, 0, 5, 6, 4) and (1, 2, 0, 4, 5, 6, 3), both with probability 543/7⁷. The next two are (1, 2, 3, 4, 0, 6, 5) and (1, 0, 3, 4, 5, 6, 2) with probability 504/7⁷. (1, 2, 3, 4, 5, 6, 0) has probability 429/7⁷. But my code could be completely out to lunch :) – rici Sep 11 at 14:46

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