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Augmenting Large Language Models via Vector Embeddings to Improve Domain-Specific Responsiveness
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Bringing Your Own View: Graph Contrastive Learning without Prefabricated Data Augmentations.

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Summary
This summary is machine-generated.

This study introduces an automated approach to graph contrastive learning (GraphCL), replacing manual data augmentation with a learnable prior. This method enhances graph representation learning without human expertise, achieving competitive results on various benchmarks.

Keywords:
Graph contrastive learninggraph generative modelinformation bottleneckinformation minimization

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Area of Science:

  • Artificial Intelligence
  • Machine Learning
  • Graph Representation Learning

Background:

  • Self-supervision is advancing graph learning, but current methods like GraphCL rely on manual data augmentation.
  • This reliance on domain knowledge and trial-and-error limits the efficiency and scalability of graph representation learning.

Purpose of the Study:

  • To develop an automated framework for graph contrastive learning (GraphCL).
  • To address the limitations of manual data augmentation in GraphCL by learning a continuous prior in the parameter space of graph generators.
  • To integrate principles of information minimization (InfoMin) and information bottleneck (InfoBN) for regularizing learned priors and preventing trivial solutions.

Main Methods:

  • Extended GraphCL by moving from discrete augmentations to a learnable continuous prior in graph generator parameters.
  • Leveraged InfoMin and InfoBN principles to regularize learned priors.
  • Developed a bi-level optimization framework integrating contrastive learning, InfoMin, and InfoBN.

Main Results:

  • The automated approach demonstrates competitive performance against state-of-the-art self-supervision methods on small graph benchmarks.
  • Achieved superior generalizability on large-scale graphs compared to existing methods.
  • Eliminated the need for human expertise or downstream validation in the augmentation process.

Conclusions:

  • The proposed principled and automated framework significantly advances GraphCL by enabling learnable priors.
  • This method offers a more efficient and generalizable approach to self-supervised graph representation learning.
  • The successful application on diverse benchmarks highlights the potential of automated graph augmentation.