Multiscale Grassmann Manifolds for Single-Cell Data Analysis
Abstract
Single-cell data analysis seeks to characterize cellular heterogeneity based on high-dimensional gene expression profiles. Conventional approaches represent each cell as a vector in Euclidean space, which limits their ability to capture intrinsic correlations and multiscale geometric structures. We propose a multiscale framework based on Grassmann manifolds that integrates machine learning with subspace geometry for single-cell data analysis. By generating embeddings under multiple representation scales, the framework combines their features from different geometric views into a unified Grassmann manifold. A power-based scale sampling function is introduced to control the selection of scales and balance in- formation across resolutions. Experiments on nine benchmark single-cell RNA-seq datasets demonstrate that the proposed approach effectively preserves meaningful structures and provides stable clustering performance, particularly for small to medium-sized datasets. These results suggest that Grassmann manifolds offer a coherent and informative foundation for analyzing single cell data.
Cite
@article{arxiv.2511.11717,
title = {Multiscale Grassmann Manifolds for Single-Cell Data Analysis},
author = {Xiang Xiang Wang and Sean Cottrell and Guo-Wei Wei},
journal= {arXiv preprint arXiv:2511.11717},
year = {2025}
}