Learning on graphs with high-order relations: spectral methods, optimization and applications

Li, Pan

Permalink

https://hdl.handle.net/2142/105596 Copy

Description

Title

Learning on graphs with high-order relations: spectral methods, optimization and applications

Author(s)

Li, Pan

Issue Date

2019-06-11

Director of Research (if dissertation) or Advisor (if thesis)

Milenkovic, Olgica

Doctoral Committee Chair(s)

Milenkovic, Olgica

Committee Member(s)

• Han, Jiawei
• Hajek, Bruce
• He, Niao
• Gleich, David

Department of Study

Electrical & Computer Eng

Discipline

Electrical & Computer Engr

Degree Granting Institution

University of Illinois at Urbana-Champaign

Degree Name

Ph.D.

Degree Level

Dissertation

Keyword(s)

• hypergraph
• spectral clustering
• submodular function
• Lovasz extension
• semi-supervised learning
• PageRank

Abstract

Learning on graphs is an important problem in machine learning, computer vision and data mining. Traditional algorithms for learning on graphs primarily take into account only low-order connectivity patterns described at the level of individual vertices and edges. However, in many applications, high-order relations among vertices are necessary to properly model a real-life problem. In contrast to the low-order cases, in-depth algorithmic and analytic studies supporting high-order relations among vertices are still lacking. To address this problem, we introduce a new mathematical model family, termed inhomogeneous hypergraphs, which captures the high-order relations among vertices in a very extensive and flexible way. Specifically, as opposed to classic hypergraphs that treat vertices within a high-order structure in a uniform manner, inhomogeneous hypergraphs allow one to model the fact that different subsets of vertices within a high-order relation may have different structural importance. We propose a series of algorithms and relevant analytic results for this new model. First, after we introduce the formal definitions and some preliminaries, we propose clustering algorithms over inhomogeneous hypergraphs. The first clustering method is based on a projection method, where we use graphs with pairwise relations to approximate high-order relations and then directly use spectral clustering methods over obtained graphs. For this type of method, we provide provable performance guarantee, which works for a sub-class of inhomogeneous hypergraphs that additionally impose constraints on the internal structures of high-order relations. Such constraints are related to submodular functions, so we term such a sub-class of inhomogeneous hypergraphs as submodular hypergraphs. Later, we study the Laplacian operators for these hypergraphs and generalize many important results in spectral theory for this setting including Cheeger's inequalities and discrete nodal domain theorems. Based on these new results, we further develop new clustering algorithms with tighter approximating properties than projection methods. Second, we propose some optimization algorithms for inhomogeneous hypergraphs. We first find that min-cut problems over submodular hypergraphs are closely related to an extensively studied optimization problem termed decomposable submodular hypergraph minimization (DSFM). Our contribution is how to leverage hypergraph structures to accelerate canonical solvers for DSFM problems. Later, we connect PageRank approaches to submodular hypergraphs and propose a new optimization problem termed quadratic decomposable submodular hypergraph minimization (QDSFM). For this new problem, we propose algorithms with first provable linear convergence guarantee and identify new relevant applications.

Graduation Semester

2019-08

Type of Resource

text

Permalink

http://hdl.handle.net/2142/105596

Copyright and License Information

Copyright 2019 Pan Li

Owning Collections