Directed Graph Embeddings in Pseudo-Riemannian Manifolds

Aaron Sim; Maciej L Wiatrak; Angus Brayne; Paidi Creed; Saee Paliwal

2021 ICML ICML 2021

Directed Graph Embeddings in Pseudo-Riemannian Manifolds

Abstract

The inductive biases of graph representation learning algorithms are often encoded in the background geometry of their embedding space. In this paper, we show that general directed graphs can be effectively represented by an embedding model that combines three components: a pseudo-Riemannian metric structure, a non-trivial global topology, and a unique likelihood function that explicitly incorporates a preferred direction in embedding space. We demonstrate the representational capabilities of this method by applying it to the task of link prediction on a series of synthetic and real directed graphs from natural language applications and biology. In particular, we show that low-dimensional cylindrical Minkowski and anti-de Sitter spacetimes can produce equal or better graph representations than curved Riemannian manifolds of higher dimensions.

🌉 Interdisciplinary Bridge — Computer Science and Deep Learning and Knowledge & Reasoning and Machine Learning

🐝 Cross-Pollinator — Artificial Intelligence, Computer Science, Computer Vision, Data Science & Analytics, Deep Learning, Healthcare & Medicine, Interdisciplinary, Knowledge & Reasoning, Machine Learning, Mathematics & Optimization, Natural Language Processing, Reinforcement Learning, Robotics, Security & Privacy, Speech & Audio

Authors

Aaron Sim , Maciej L Wiatrak , Angus Brayne , Paidi Creed , Saee Paliwal

Topics

Machine Learning > Core Methods > Representation Learning Machine Learning > Core Methods > Embedding Learning Deep Learning > Architectures > Graph Neural Networks Knowledge & Reasoning > Reasoning > Graph Embeddings Computer Science > Applications > Information Retrieval

Keywords

representation learning link prediction graph representation learning graph embedding directed graph pseudo-riemannian manifold

Download PDF

Related papers

GRAND: Graph Neural Diffusion 2021

Almost Optimal Anytime Algorithm for Batched Multi-Armed Bandits 2021

Straight to the Gradient: Learning to Use Novel Tokens for Neural Text Generation 2021

Differentiable Dynamic Quantization with Mixed Precision and Adaptive Resolution 2021

Dataset Dynamics via Gradient Flows in Probability Space 2021