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Main Authors: Ju, Wei, Fang, Zheng, Gu, Yiyang, Liu, Zequn, Long, Qingqing, Qiao, Ziyue, Qin, Yifang, Shen, Jianhao, Sun, Fang, Xiao, Zhiping, Yang, Junwei, Yuan, Jingyang, Zhao, Yusheng, Wang, Yifan, Luo, Xiao, Zhang, Ming
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2304.05055
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author Ju, Wei
Fang, Zheng
Gu, Yiyang
Liu, Zequn
Long, Qingqing
Qiao, Ziyue
Qin, Yifang
Shen, Jianhao
Sun, Fang
Xiao, Zhiping
Yang, Junwei
Yuan, Jingyang
Zhao, Yusheng
Wang, Yifan
Luo, Xiao
Zhang, Ming
author_facet Ju, Wei
Fang, Zheng
Gu, Yiyang
Liu, Zequn
Long, Qingqing
Qiao, Ziyue
Qin, Yifang
Shen, Jianhao
Sun, Fang
Xiao, Zhiping
Yang, Junwei
Yuan, Jingyang
Zhao, Yusheng
Wang, Yifan
Luo, Xiao
Zhang, Ming
contents Graph representation learning aims to effectively encode high-dimensional sparse graph-structured data into low-dimensional dense vectors, which is a fundamental task that has been widely studied in a range of fields, including machine learning and data mining. Classic graph embedding methods follow the basic idea that the embedding vectors of interconnected nodes in the graph can still maintain a relatively close distance, thereby preserving the structural information between the nodes in the graph. However, this is sub-optimal due to: (i) traditional methods have limited model capacity which limits the learning performance; (ii) existing techniques typically rely on unsupervised learning strategies and fail to couple with the latest learning paradigms; (iii) representation learning and downstream tasks are dependent on each other which should be jointly enhanced. With the remarkable success of deep learning, deep graph representation learning has shown great potential and advantages over shallow (traditional) methods, there exist a large number of deep graph representation learning techniques have been proposed in the past decade, especially graph neural networks. In this survey, we conduct a comprehensive survey on current deep graph representation learning algorithms by proposing a new taxonomy of existing state-of-the-art literature. Specifically, we systematically summarize the essential components of graph representation learning and categorize existing approaches by the ways of graph neural network architectures and the most recent advanced learning paradigms. Moreover, this survey also provides the practical and promising applications of deep graph representation learning. Last but not least, we state new perspectives and suggest challenging directions which deserve further investigations in the future.
format Preprint
id arxiv_https___arxiv_org_abs_2304_05055
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A Comprehensive Survey on Deep Graph Representation Learning
Ju, Wei
Fang, Zheng
Gu, Yiyang
Liu, Zequn
Long, Qingqing
Qiao, Ziyue
Qin, Yifang
Shen, Jianhao
Sun, Fang
Xiao, Zhiping
Yang, Junwei
Yuan, Jingyang
Zhao, Yusheng
Wang, Yifan
Luo, Xiao
Zhang, Ming
Machine Learning
Artificial Intelligence
Information Retrieval
Graph representation learning aims to effectively encode high-dimensional sparse graph-structured data into low-dimensional dense vectors, which is a fundamental task that has been widely studied in a range of fields, including machine learning and data mining. Classic graph embedding methods follow the basic idea that the embedding vectors of interconnected nodes in the graph can still maintain a relatively close distance, thereby preserving the structural information between the nodes in the graph. However, this is sub-optimal due to: (i) traditional methods have limited model capacity which limits the learning performance; (ii) existing techniques typically rely on unsupervised learning strategies and fail to couple with the latest learning paradigms; (iii) representation learning and downstream tasks are dependent on each other which should be jointly enhanced. With the remarkable success of deep learning, deep graph representation learning has shown great potential and advantages over shallow (traditional) methods, there exist a large number of deep graph representation learning techniques have been proposed in the past decade, especially graph neural networks. In this survey, we conduct a comprehensive survey on current deep graph representation learning algorithms by proposing a new taxonomy of existing state-of-the-art literature. Specifically, we systematically summarize the essential components of graph representation learning and categorize existing approaches by the ways of graph neural network architectures and the most recent advanced learning paradigms. Moreover, this survey also provides the practical and promising applications of deep graph representation learning. Last but not least, we state new perspectives and suggest challenging directions which deserve further investigations in the future.
title A Comprehensive Survey on Deep Graph Representation Learning
topic Machine Learning
Artificial Intelligence
Information Retrieval
url https://arxiv.org/abs/2304.05055