An effective Mayer-Vietoris Theorem for discrete Morse homology

TL;DR

This paper introduces an explicit, effective version of the Mayer-Vietoris theorem for discrete Morse homology, enabling direct computation of homology groups of a complex from gradient vector fields without prior homology knowledge.

Contribution

It provides a new theorem that explicitly computes homology using gradient vector fields, bypassing the need for prior homology calculations of subcomplexes.

Findings

Homology groups can be computed explicitly from gradient trajectories.

The method reduces computational complexity when subcomplexes admit efficient gradient fields.

The approach is applicable regardless of the coherence of gradient vector fields on intersections.

Abstract

The Mayer-Vietoris theorem is known for its wide applications, especially in determining homology. In fact, this theorem provides us with a long exact sequence, where the underlying homology groups fit in. However, this theorem does not provide an explicit way to compute homology. In this paper we prove an ``effective" version of the Mayer-Vietoris theorem using discrete Morse theory. Suppose, we have a Mayer-Vietoris type setup, i.e., let $X$ be a simplicial complex and $A$ and $B$ be two subcomplexes of $X$, such that $A \cup B=X$. Moreover, let $\mathcal{W}_A$, $\mathcal{W}_{B}$ and $\mathcal{W}_{A \cap B}$ be gradient vector fields on $A$, $B$ and $A \cap B$ respectively (which need not be ``coherent", i.e., they do not need to coincide on their intersection). Then, the main theorem of our paper provides an explicit way to compute the homology groups of $X$, using the combinatorial information regarding the trajectories of the aforementioned gradient vector fields, we do not even need to know the individual homology groups $H_{*}(A)$, $H_{*}(B)$ and $H_{*}(A \cap B)$. In principle, the homology of $X$ can always be computed explicitly using our theorem irrespective of the choice of the gradient vector fields. Further, if we choose the subcomplexes $A$ and $B$ wisely so that each of $A$, $B$ and $A \cap B$ admits an efficient gradient vector field, then the computation of the homology groups is considerably reduced.