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VIGraph: Generative Self-supervised Learning for Class-Imbalanced Node Classification


Kernekoncepter
VIGraph introduces a novel approach to address class-imbalanced node classification by generating high-quality nodes directly usable for classification.
Resumé

The content discusses the challenges of class imbalance in graph data and introduces VIGraph as a solution. It delves into the shortcomings of existing methods, particularly in constructing imbalanced graphs. VIGraph relies on Variational Graph Autoencoder (VGAE) and introduces comprehensive training strategies to generate high-quality nodes for minority classes. Extensive experiments demonstrate the superiority and generality of VIGraph.

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Statistik
Cora, CiteSeer, PubMed datasets used for experiments. GraphSmote, GraphMixup, ImGCL, ReNode methods discussed. VIGraph outperformed other methods in experiments.
Citater
"VIGraph introduces comprehensive training strategies to generate high-quality nodes directly usable for classification." "VIGraph is more stable than other models under various imbalance ratios, even in extreme imbalance scenarios."

Vigtigste indsigter udtrukket fra

by Yulan Hu,She... kl. arxiv.org 03-28-2024

https://arxiv.org/pdf/2311.01191.pdf
VIGraph

Dybere Forespørgsler

How does VIGraph's approach to generating nodes differ from traditional methods like GraphSmote

VIGraph's approach to generating nodes differs significantly from traditional methods like GraphSmote. While GraphSmote and similar methods focus on synthesizing new samples for minority classes based on the original balanced graph, VIGraph takes a more rigorous approach. VIGraph constructs an imbalanced graph from the outset by directly removing a portion of nodes and their connecting edges. This ensures that the node representations used for generating new nodes are learned from the imbalanced graph itself, maximizing the simulation of real-world imbalanced scenarios. In contrast, GraphSmote and other methods may use representations trained on the original balanced graph, leading to biased class-imbalanced node classification results. Additionally, VIGraph directly integrates the generated nodes with the original labeled node set, eliminating the need for additional training steps found in traditional methods.

What are the implications of VIGraph's performance across different backbone models

The performance of VIGraph across different backbone models showcases its universality and stability. VIGraph consistently outperformed other baselines across various datasets, demonstrating its effectiveness in generating high-quality samples for minority classes. The results indicate that VIGraph's approach is robust and can adapt well to different backbone models, highlighting its versatility and reliability in addressing class-imbalanced node classification tasks. This performance consistency across different backbone models underscores the strength and reliability of VIGraph's generative self-supervised learning approach.

How can the concept of generative self-supervised learning be applied to other areas beyond node classification

The concept of generative self-supervised learning, as demonstrated by VIGraph in the context of class-imbalanced node classification, can be applied to various other areas beyond node classification. In natural language processing, generative self-supervised learning models can be utilized for tasks like text generation, language modeling, and machine translation. In computer vision, these models can aid in image generation, image inpainting, and video prediction tasks. Additionally, in reinforcement learning, generative self-supervised learning can be beneficial for generating diverse and realistic environments for training agents. The versatility and effectiveness of generative self-supervised learning, as exemplified by VIGraph, make it a promising approach for a wide range of machine learning tasks beyond node classification.
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