TIEJ5100 COM1: Graph Neural Networks (JSS34) (1 cr)

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Study level:
Postgraduate studies
Grading scale:
Pass - fail
Language:
English
Responsible organisation:
Faculty of Information Technology
Curriculum periods:
2025-2026

Description

Relational learning

  • Overview
  • Graph neural networks (GNNs)
  • Spectral perspective
  • Spatial perspective
  • Main architectures
  • Dealing with oversmoothing and oversquashing
  • Theory of GNNs
  • Expressivity
  • Generalization
  • Extensions
  • High-order GNNs
  • GNNs for knowledge graphs
  • Graph Transformers
  • Hypergraph neural networks
  • Topological neural networks
  • Generative models for graphs

Learning outcomes

Understanding main concepts and methods in relational learning  

Description of prerequisites

Minimum: basic level machine learning courses. Recommended: advanced courses on machine learning and deep learning 

Study materials

  • William L. Hamilton, Graph Representation Learning. Synthesis Lectures on AI and ML, Vol. 14, No. 3. 2020.
  • Michael M. Bronstein and Joan Bruna and Taco Cohen and Petar Veličković, Geometric Deep Learning: Grids, Groups, Graphs, Geodesics, and Gauges. ArXiv, 2021.
  • L. Wu, P. Cui, J. Pei, and L. Zhao. Graph Neural Networks: Foundations, Frontiers, and Applications. Springer, Singapore, 2022
  • M. Hajij et. al., Topological Deep Learning: Going Beyond Graph Data. ArXiv, 2023.
  • Stefanie Jegelka. Theory of Graph Neural Networks: Representation and Learning. ArXiv, 2022.

Completion methods

Method 1

Description:
Lectures and demonstrations. Each student is required to give a presentation on the final day.
Evaluation criteria:
Pass/fail
Time of teaching:
Period 1
Select all marked parts
Parts of the completion methods
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Participation in teaching (1 cr)

Type:
Participation in teaching
Grading scale:
Pass - fail
Evaluation criteria:
<p>Pass/fail</p>
Language:
English
Study methods:

Lectures and demonstrations. Each student is required to give a presentation on the final day.

Study materials:
  • William L. Hamilton, Graph Representation Learning. Synthesis Lectures on AI and ML, Vol. 14, No. 3. 2020.
  • Michael M. Bronstein and Joan Bruna and Taco Cohen and Petar Veličković, Geometric Deep Learning: Grids, Groups, Graphs, Geodesics, and Gauges. ArXiv, 2021.
  • L. Wu, P. Cui, J. Pei, and L. Zhao. Graph Neural Networks: Foundations, Frontiers, and Applications. Springer, Singapore, 2022
  • M. Hajij et. al., Topological Deep Learning: Going Beyond Graph Data. ArXiv, 2023.
  • Stefanie Jegelka. Theory of Graph Neural Networks: Representation and Learning. ArXiv, 2022.

Teaching