Bibliographic Information: Das, P., & Mawiong, S. M. (2024). Multiple Cylinder of Relations for Finite Spaces and Nerve Theorem for Strong-Good Cover. arXiv preprint arXiv:2411.09281v1.
Research Objective: This paper aims to extend the existing tools for studying the homotopy types of finite spaces and simplicial complexes. The authors introduce the concept of a "multiple cylinder of relations" and a stronger version of the Nerve Theorem based on "strong-good covers."
Methodology: The authors develop the concept of the multiple cylinder of relations as a generalization of the relation cylinder and the multiple non-Hausdorff mapping cylinder. They then define strong-good covers for simplicial complexes and finite spaces, where intersections are required to be collapsible rather than just contractible. Using these new concepts, they prove stronger versions of the Nerve Theorem for both finite spaces and simplicial complexes.
Key Findings:
Main Conclusions: The introduction of the multiple cylinder of relations and the concept of strong-good covers provide powerful new tools for studying the homotopy types of finite spaces and simplicial complexes. These tools offer finer control and stronger results compared to classical methods, opening up new avenues for research in combinatorial topology and related fields.
Significance: This research significantly contributes to the field of topological data analysis by providing new theoretical frameworks and tools for analyzing complex datasets represented as finite spaces or simplicial complexes. The stronger Nerve Theorem, in particular, offers a more robust way to relate the homotopy type of a space to the nerve of a cover, potentially leading to more efficient algorithms and insights in applications.
Limitations and Future Research: The paper primarily focuses on theoretical developments. Future research could explore the practical implications of these findings, developing algorithms and applications that leverage the multiple cylinder of relations and strong-good covers for data analysis tasks. Additionally, investigating the relationship between strong-good covers and other types of covers in topological data analysis could yield further insights.
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by Ponaki Das, ... a las arxiv.org 11-15-2024
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