The persistent homology of the Linial-Meshulam process
Abstract
For a fixed dimension k 1, let us consider the randomly growing simplical complex on the vertex set \1,2,…,n\ defined as follows: We start with the empty complex, and for each k+1-element subset σ of \1,2,…,n\, we add σ and all of its subsets to the complex at some random time tσ, where (tσ) are i.i.d. uniform random elements of [0,n]. As the complex evolves, new k-1-dimensional cycles are born and then at a later time they die, that is, they get filled in. The notion of persistence diagrams, which is a standard tool in topological data analysis, provides a way to record these birth and death times. In this paper, we understand the asymptotic behavior of the persistence diagrams of the above defined randomly evolving complexes as n goes to infinity. As the single time marginals of the above process are variants of the Linial-Meshulam complex, our results can be viewed as extensions of the results of Linial and Peled on the Betti numbers of the Linial-Meshulam complex. Our proof relies on the notion of local weak convergence of graphs and a generalization of the results of Bordenave, Lelarge and Salez on the rank of sparse random matrices.
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