Invertible Manifold Learning for Dimension Reduction
Abstract
Dimension reduction (DR) aims to learn low-dimensional representations of high-dimensional data with the preservation of essential information. In the context of manifold learning, we define that the representation after information-lossless DR preserves the topological and geometric properties of data manifolds formally, and propose a novel two-stage DR method, called invertible manifold learning (inv-ML) to bridge the gap between theoretical information-lossless and practical DR. The first stage includes a homeomorphic sparse coordinate transformation to learn low-dimensional representations without destroying topology and a local isometry constraint to preserve local geometry. In the second stage, a linear compression is implemented for the trade-off between the target dimension and the incurred information loss in excessive DR scenarios. Experiments are conducted on seven datasets with a neural network implementation of inv-ML, called i-ML-Enc. Empirically, i-ML-Enc achieves invertible DR in comparison with typical existing methods as well as reveals the characteristics of the learned manifolds. Through latent space interpolation on real-world datasets, we find that the reliability of tangent space approximated by the local neighborhood is the key to the success of manifold-based DR algorithms.
Cite
@article{arxiv.2010.04012,
title = {Invertible Manifold Learning for Dimension Reduction},
author = {Siyuan Li and Haitao Lin and Zelin Zang and Lirong Wu and Jun Xia and Stan Z. Li},
journal= {arXiv preprint arXiv:2010.04012},
year = {2021}
}
Comments
ECML-PKDD 2021 camera-ready. 15 pages (main) with 10 pages appendix