An Algorithm for Correct Computation of Reeb Spaces for PL Bivariate Fields

The Reeb space is a topological structure which is a generalization of the notion of the Reeb graph to multi-fields. Its effectiveness has been established in revealing topological features in data across diverse computational domains which cannot be identified using the Reeb graph or other scalar-topology-based methods. Approximations of Reeb spaces such as the Mapper and the Joint Contour Net have been developed based on quantization of the range. However, computing the topologically correct Reeb space dispensing the range-quantization is a challenging problem. In the current paper, we develop an algorithm for computing a correct net-like approximation corresponding to the Reeb space of a generic piecewise-linear (PL) bivariate field based on a multi-dimensional Reeb graph (MDRG). First, we prove that the Reeb space is homeomorphic to its MDRG. Subsequently, we introduce an algorithm for computing the MDRG of a generic PL bivariate field through the computation of its Jacobi set and Jacobi structure, a projection of the Jacobi set into the Reeb space. This marks the first algorithm for MDRG computation without requiring the quantization of bivariate fields. Following this, we compute a net-like structure embedded in the corresponding Reeb space using the MDRG and the Jacobi structure. We provide the proof of correctness and complexity analysis of our algorithm.