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A Novel Regularized Principal Graph Learning Framework on Explicit Graph Representation

Artificial Intelligence 2016-01-19 v2 Machine Learning Machine Learning

Abstract

Many scientific datasets are of high dimension, and the analysis usually requires visual manipulation by retaining the most important structures of data. Principal curve is a widely used approach for this purpose. However, many existing methods work only for data with structures that are not self-intersected, which is quite restrictive for real applications. A few methods can overcome the above problem, but they either require complicated human-made rules for a specific task with lack of convergence guarantee and adaption flexibility to different tasks, or cannot obtain explicit structures of data. To address these issues, we develop a new regularized principal graph learning framework that captures the local information of the underlying graph structure based on reversed graph embedding. As showcases, models that can learn a spanning tree or a weighted undirected 1\ell_1 graph are proposed, and a new learning algorithm is developed that learns a set of principal points and a graph structure from data, simultaneously. The new algorithm is simple with guaranteed convergence. We then extend the proposed framework to deal with large-scale data. Experimental results on various synthetic and six real world datasets show that the proposed method compares favorably with baselines and can uncover the underlying structure correctly.

Keywords

Cite

@article{arxiv.1512.02752,
  title  = {A Novel Regularized Principal Graph Learning Framework on Explicit Graph Representation},
  author = {Qi Mao and Li Wang and Ivor W. Tsang and Yijun Sun},
  journal= {arXiv preprint arXiv:1512.02752},
  year   = {2016}
}
R2 v1 2026-06-22T12:04:57.508Z