# Approximation of Metric Spaces by Reeb Graphs: Cycle Rank of a Reeb   Graph, the Co-rank of the Fundamental Group, and Large Components of Level   Sets on Riemannian Manifolds

**Authors:** Irina Gelbukh

arXiv: 1903.00777 · 2019-03-06

## TL;DR

This paper establishes bounds on the cycle rank of Reeb graphs in relation to the fundamental group of the underlying space, providing practical methods for calculation and applications to Gromov-Hausdorff approximation and Riemannian manifolds.

## Contribution

It introduces bounds linking Reeb graph cycle rank to the co-rank of the fundamental group and applies these bounds to improve approximation estimates for metric spaces.

## Key findings

- Cycle rank of Reeb graph is bounded by the co-rank of the fundamental group.
- Provided practical methods for calculating the co-rank and isotropy index.
- Established a lower bound on Reeb width for Riemannian manifolds.

## Abstract

For a connected locally path-connected topological space $X$ and a continuous function $f$ on it such that its Reeb graph $R_f$ is a finite topological graph, we show that the cycle rank of $R_f$, i.e., the first Betti number $b_1(R_f)$, in computational geometry called \emph{number of loops}, is bounded from above by the co-rank of the fundamental group $\pi_1(X)$, the condition of local path-connectedness being important since generally $b_1(R_f)$ can even exceed $b_1(X)$. We give some practical methods for calculating the co-rank of $\pi_1(X)$ and a closely related value, the isotropy index. We apply our bound to improve upper bounds on the distortion of the Reeb quotient map, and thus on the Gromov-Hausdorff approximation of the space by Reeb graphs, for the distance function on a compact geodesic space and for a simple Morse function on a closed Riemannian manifold. This distortion is bounded from below by what we call the Reeb width $b(M)$ of a metric space $M$, which guarantees that any real-valued continuous function on $M$ has large enough contour (connected component of a level set). We show that for a Riemannian manifold, $b(M)$ is non-zero and give a lower bound on it in terms of characteristics of the manifold. In particular, we show that any real-valued continuous function on a closed Euclidean unit ball $E$ of dimension at least two has a contour $C$ with $diam(C\cap\partial E)\ge\sqrt3$.

---
Source: https://tomesphere.com/paper/1903.00777