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Auteurs principaux: Widdowson, Daniel E, Kurlin, Vitaliy A
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2509.15088
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author Widdowson, Daniel E
Kurlin, Vitaliy A
author_facet Widdowson, Daniel E
Kurlin, Vitaliy A
contents Periodic point sets model all solid crystalline materials (crystals) whose atoms can be considered zero-sized points with or without atomic types. This paper addresses the fundamental problem of checking whether claimed crystals are novel, not noisy perturbations of known materials obtained by unrealistic atomic replacements. Such near-duplicates have skewed ground-truth because past comparisons relied on unstable cells and symmetries. The proposed Lipschitz continuity under noise is a new essential requirement for machine learning on any data objects that have ambiguous representations and live in continuous spaces. For periodic point sets under isometry (any distance-preserving transformation), we designed invariants that distinguish all known counter-examples to the completeness of past descriptors and detect thousands of (near-)duplicates in large high-profile databases of crystals within two days on a modest desktop computer.
format Preprint
id arxiv_https___arxiv_org_abs_2509_15088
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Higher-order, generically complete, continuous, and polynomial-time isometry invariants of periodic sets
Widdowson, Daniel E
Kurlin, Vitaliy A
Computational Geometry
Materials Science
52C07, 52C25, 51N20, 11H06
Periodic point sets model all solid crystalline materials (crystals) whose atoms can be considered zero-sized points with or without atomic types. This paper addresses the fundamental problem of checking whether claimed crystals are novel, not noisy perturbations of known materials obtained by unrealistic atomic replacements. Such near-duplicates have skewed ground-truth because past comparisons relied on unstable cells and symmetries. The proposed Lipschitz continuity under noise is a new essential requirement for machine learning on any data objects that have ambiguous representations and live in continuous spaces. For periodic point sets under isometry (any distance-preserving transformation), we designed invariants that distinguish all known counter-examples to the completeness of past descriptors and detect thousands of (near-)duplicates in large high-profile databases of crystals within two days on a modest desktop computer.
title Higher-order, generically complete, continuous, and polynomial-time isometry invariants of periodic sets
topic Computational Geometry
Materials Science
52C07, 52C25, 51N20, 11H06
url https://arxiv.org/abs/2509.15088