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Main Authors: Arulandu, Alvan, Gottschalk, Daniel, Payne, Thomas, Richardson, Alexander, Weighill, Thomas
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2510.24472
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author Arulandu, Alvan
Gottschalk, Daniel
Payne, Thomas
Richardson, Alexander
Weighill, Thomas
author_facet Arulandu, Alvan
Gottschalk, Daniel
Payne, Thomas
Richardson, Alexander
Weighill, Thomas
contents We introduce a new measure of distance between datasets, based on vineyards from topological data analysis, which we call the vineyard distance. Vineyard distance measures the extent of topological change along an interpolation from one dataset to another, either along a pre-computed trajectory or via a straight-line homotopy. We demonstrate through theoretical results and experiments that vineyard distance is less sensitive than $L^p$ distance (which considers every single data value), but more sensitive than Wasserstein distance between persistence diagrams (which accounts only for shape and not location). This allows vineyard distance to reveal distinctions that the other two distance measures cannot. In our paper, we establish theoretical results for vineyard distance including as upper and lower bounds. We then demonstrate the usefulness of vineyard distance on real-world data through applications to geospatial data and to neural network training dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2510_24472
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Through the Grapevine: Vineyard Distance as a Measure of Topological Dissimilarity
Arulandu, Alvan
Gottschalk, Daniel
Payne, Thomas
Richardson, Alexander
Weighill, Thomas
Algebraic Topology
55N31
We introduce a new measure of distance between datasets, based on vineyards from topological data analysis, which we call the vineyard distance. Vineyard distance measures the extent of topological change along an interpolation from one dataset to another, either along a pre-computed trajectory or via a straight-line homotopy. We demonstrate through theoretical results and experiments that vineyard distance is less sensitive than $L^p$ distance (which considers every single data value), but more sensitive than Wasserstein distance between persistence diagrams (which accounts only for shape and not location). This allows vineyard distance to reveal distinctions that the other two distance measures cannot. In our paper, we establish theoretical results for vineyard distance including as upper and lower bounds. We then demonstrate the usefulness of vineyard distance on real-world data through applications to geospatial data and to neural network training dynamics.
title Through the Grapevine: Vineyard Distance as a Measure of Topological Dissimilarity
topic Algebraic Topology
55N31
url https://arxiv.org/abs/2510.24472