Expected Complexity of Persistent Homology Computation via Matrix Reduction

We study the algorithmic complexity of computing persistent homology of a randomly generated filtration. Specifically, we prove upper bounds for the average fill-in (number of non-zero entries) of the boundary matrix on \v{C}ech, Vietoris--Rips and Erd\H{o}s--R\'enyi filtrations after matrix reduction. Our bounds show that the reduced matrix is expected to be significantly sparser than what the general worst-case predicts. Our method is based on previous results on the expected Betti numbers of the corresponding complexes. We establish a link between these results and the fill-in of the boundary matrix. In the $1$-dimensional case, our bound for \v{C}ech and Vietoris--Rips complexes is asymptotically tight up to a logarithmic factor. We also provide an Erd\H{o}s--R\'enyi filtration realising the worst-case.