English

Ungarian Markov Chains

Combinatorics 2025-07-29 v1 Probability

Abstract

We introduce the Ungarian Markov chain UL{\bf U}_L associated to a finite lattice LL. The states of this Markov chain are the elements of LL. When the chain is in a state xLx\in L, it transitions to the meet of {x}T\{x\}\cup T, where TT is a random subset of the set of elements covered by xx. We focus on estimating E(L)\mathcal E(L), the expected number of steps of UL{\bf U}_L needed to get from the top element of LL to the bottom element of LL. Using direct combinatorial arguments, we provide asymptotic estimates when LL is the weak order on the symmetric group SnS_n and when LL is the nn-th Tamari lattice. When LL is distributive, the Markov chain UL{\bf U}_L is equivalent to an instance of the well-studied random process known as last-passage percolation with geometric weights. One of our main results states that if LL is a trim lattice, then E(L)E(spine(L))\mathcal E(L)\leq\mathcal E(\text{spine}(L)), where spine(L)\text{spine}(L) is a specific distributive sublattice of LL called the spine of LL. Combining this lattice-theoretic theorem with known results about last-passage percolation yields a powerful method for proving upper bounds for E(L)\mathcal E(L) when LL is trim. We apply this method to obtain uniform asymptotic upper bounds for the expected number of steps in the Ungarian Markov chains of Cambrian lattices of classical types and the Ungarian Markov chains of ν\nu-Tamari lattices.

Keywords

Cite

@article{arxiv.2301.08206,
  title  = {Ungarian Markov Chains},
  author = {Colin Defant and Rupert Li},
  journal= {arXiv preprint arXiv:2301.08206},
  year   = {2025}
}

Comments

36 pages, 9 figures

R2 v1 2026-06-28T08:15:35.785Z