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I have a number of ordered lists, most containing the same elements. I want to find the most probable order of the elements from the lists (samples).

Example:

l1={ a, b, f, h, z }
l2={ c, e, h, x, z }
l3={ a, e, y, z }
l4={ b, e, f, z }

The result should be:

R={a, b, c, e, f, h, x, y, z}; or 
R={ a,b,c,e,f,h,y,x,z }

The elements have no information regarding their natural order. The order should be learned from the lists, and in some cases the order in a list may contradict other lists, so I need the most probable order. I have about 175,000 lists, for about 1.8 million elements (total, 260k unique), the number of elements per list varies.

I have already tried building a directed graph where the edges have the number of lists that connect the vertices in such order, and then went through all the paths to find the most probable sequence. This approach works well for small problems, but it is way too complex for a problem this large.

Any pointers, please, will be greatly appreciated.

Thanks.

Juan

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  • you do have many elements, but is your dictionary also large? or just letters from a to z?
    – fr_andres
    May 25, 2017 at 3:17
  • The elements are just objects. Uniqueness is defined by their hash code. The letters above is an example to show easily the problem I am trying to solve, letters have nothing to do with the real elements. There are approx. 260,000 unique elements.
    – jfarjona
    May 25, 2017 at 3:22
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    hm... if you can afford to have a 2GB datastructure (assuming your hash values are about 4 bytes), I would try to implement a topological sorting of the graph, with each a->b connection having a weight equal to the number of times a directly preceded b
    – fr_andres
    May 25, 2017 at 3:40
  • and then collapse that datastructure (some kind of hash or adjacency list) to a linked list, taking first the connections with higher weights. It can even be possible that such greedy approach maximizes the likelihood and no machine learning is needed
    – fr_andres
    May 25, 2017 at 3:43
  • actually you have to store both a->b and b->a weights, but i think you could do that with 2-byte or even 1-byte unsigned integers. And when collapsing, you would simply take the biggest one (should be anyway a big difference if your dataset is consistent)
    – fr_andres
    May 25, 2017 at 3:51

1 Answer 1

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I think your problem is very similar to that of developing a player rating system for multiplayer games. Unfortunately, I don't see an easy answer for this, especially given your volume of data. I would be inclined to treat each list of N elements as N-1 two-player games, each recording a contest between a player and the player just above them on the list. If you can afford it you could treat each list as N(N-1)/2 two-player games, recording all comparisons within the list. In either case, you could then apply a ratings system for two-player games, such as https://en.wikipedia.org/wiki/Elo_rating_system.

Another approach would be to write down a penalty function for the goodness of fit of any ordering, and then try to minimise the penalty. There are a number of functions which compare two lists with each other, such as https://en.wikipedia.org/wiki/Spearman's_rank_correlation_coefficient and https://en.wikipedia.org/wiki/Kendall_rank_correlation_coefficient. Kendall's rank correlation is just based on the number of pairwise comparisons that you would get wrong in one list if you used the other as a predictor, so it might have some nice properties. You could decide that your penalty for the overall list was the sum of all the penalties that you compute when you compare your overall list with each of the input lists in turn.

One way to minimize such a penalty would be to start with a random ordering and then repeatedly remove an item from the ordering and put it back at whichever place minimizes the penalty function, until no such change improves matters. Unfortunately, given your volume of data, I don't think you can afford this.

If you are prepared to turn your data into a list of two-player games between players of unknown strengths, then there are a variety of approach you can take. If you represent the strengths of all the players by an single vector, such as (strengthA, strengthB, strengthC,...) then the probability of A beating B might depend on the dot product of this vector with the vector (1, -1, 0, ....). This suggests that you could try finding a good fit with logistic regression, a perceptron-based model, or support vector machines.

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  • Thanks - of course if you are prepared to look at the data as a list of two-player games there a variety of ML ways to fit for underlying player strengths - I have edited my answer to add this.
    – mcdowella
    May 29, 2017 at 4:07

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