On learning mixture models for permutations

In this paper we consider the problem of learning a mixture of permutations, where each component of the mixture is generated by a stochastic process. Learning permutation mixtures arises in practical settings when a set of items is ranked by diffierent sub-populations and the rankings of users in a sub-population tend to agree with each other. While there is some applied work on learning such mixtures, they have been mostly heuristic in nature. We study the problem where the permutations in a mixture component are generated by the classical Mallows process in which each component is associated with a center and a scalar parameter. We show that even when the centers are arbitrarily separated, with exponentially many samples one can learn the mixture, provided the parameters are all the same and known; we also show that the latter two assumptions are information-theoretically inevitable. We then focus on polynomial-time learnability and show bounds on the performance of two simple algorithms for the case when the centers are well separated. Conceptually, our work suggests that while permutations may not enjoy as nice mathematical properties as Gaussians, certain structural aspects can still be exploited towards analyzing the corresponding mixture learning problem.