Rootlets Hierarchical Principal Component Analysis for Revealing Nested Dependencies in Hierarchical Data.

IF 2.2 3区数学 Q1 MATHEMATICS

Mathematics Pub Date : 2025-01-01 Epub Date: 2024-12-28 DOI:10.3390/math13010072

Korey P Wylie, Jason R Tregellas

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引用次数: 0

Abstract

Hierarchical clustering analysis (HCA) is a widely used unsupervised learning method. Limitations of HCA, however, include imposing an artificial hierarchy onto non-hierarchical data and fixed two-way mergers at every level. To address this, the current work describes a novel rootlets hierarchical principal component analysis (hPCA). This method extends typical hPCA using multivariate statistics to construct adaptive multiway mergers and Riemannian geometry to visualize nested dependencies. The rootlets hPCA algorithm and its projection onto the Poincaré disk are presented as examples of this extended framework. The algorithm constructs high-dimensional mergers using a single parameter, interpreted as a $p$ -value. It decomposes a similarity matrix from $G L (m, R)$ using a sequence of rotations from $S O (k)$ , $k ≪ m$ . Analysis shows that the rootlets algorithm limits the number of distinct eigenvalues for any merger. Nested clusters of arbitrary size but equal correlations are constructed and merged using their leading principal components. The visualization method then maps elements of $S O (k)$ onto a low-dimensional hyperbolic manifold, the Poincaré disk. Rootlets hPCA was validated using simulated datasets with known hierarchical structure, and a neuroimaging dataset with an unknown hierarchy. Experiments demonstrate that rootlets hPCA accurately reconstructs known hierarchies and, unlike HCA, does not impose a hierarchy on data.

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Rootlets层次主成分分析揭示层次数据中嵌套依赖关系。

层次聚类分析（HCA）是一种应用广泛的无监督学习方法。然而，HCA的局限性包括在非分层数据上强加人为的分层，以及在每个层次上固定的双向合并。为了解决这个问题，目前的工作描述了一种新的根状结构层次主成分分析（hPCA）。该方法扩展了典型的hPCA，利用多元统计构造自适应多路合并，利用黎曼几何可视化嵌套依赖关系。作为扩展框架的例子，给出了rootlets hPCA算法及其在poincarcarcars磁盘上的投影。该算法使用单个参数构建高维合并，解释为p值。它利用S O (k)、k≪m的旋转序列，从G L （m， R）分解出一个相似矩阵。分析表明，该算法限制了任意合并的不同特征值的数量。嵌套簇的任意大小，但相等的相关性是构建和合并使用他们的主要成分。可视化方法然后将S O (k)的元素映射到一个低维双曲流形，即庞卡罗圆盘上。Rootlets hPCA使用具有已知层次结构的模拟数据集和具有未知层次结构的神经成像数据集进行验证。实验表明，rootlets hPCA准确地重建了已知的层次结构，并且不像HCA那样对数据施加层次结构。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Mathematics Mathematics-General Mathematics

CiteScore

4.00

自引率

16.70%

发文量

4032

审稿时长

21.9 days

期刊介绍： Mathematics (ISSN 2227-7390) is an international, open access journal which provides an advanced forum for studies related to mathematical sciences. It devotes exclusively to the publication of high-quality reviews, regular research papers and short communications in all areas of pure and applied mathematics. Mathematics also publishes timely and thorough survey articles on current trends, new theoretical techniques, novel ideas and new mathematical tools in different branches of mathematics.