Network Representation Learning: A Survey

Zhang, Chengqi; Yin, Jie; Zhu, Xingquan

doi:10.1109/tbdata.2018.2850013

Cited by 572 publications

(390 citation statements)

References 95 publications

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“…Graphs are useful data structures to efficiently represent relationships among items. Due to the proliferation of graph data [54,56], a large variety of specific problems initiated significant research efforts from the Machine Learning community, aiming at extracting relevant information from such structures. This includes node clustering [33], influence maximization [21], graph generation [45] and link prediction, on which we focus in this paper.…”

Section: Introductionmentioning

confidence: 99%

“…The Adamic-Adar and Katz indices [29], reflecting neighborhood structure and node proximity, are notorious examples of such similarity indices. More recently, along with the increasing efforts in extending Deep Learning methods to graph structures [6,43,54], these approaches have been outperformed by the node embedding paradigm [16,46,56]. In a nutshell, the strategy is to train graph neural networks to represent nodes as vectors in a low-dimensional vector space, namely the embedding space.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Gravity-Inspired Graph Autoencoders for Directed Link Prediction

Salha

Limnios

Hennequin³

et al. 2019

Proceedings of the 28th ACM International Conference on Information and Knowledge Management

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Graph autoencoders (AE) and variational autoencoders (VAE) recently emerged as powerful node embedding methods. In particular, graph AE and VAE were successfully leveraged to tackle the challenging link prediction problem, aiming at figuring out whether some pairs of nodes from a graph are connected by unobserved edges. However, these models focus on undirected graphs and therefore ignore the potential direction of the link, which is limiting for numerous real-life applications. In this paper, we extend the graph AE and VAE frameworks to address link prediction in directed graphs. We present a new gravity-inspired decoder scheme that can effectively reconstruct directed graphs from a node embedding. We empirically evaluate our method on three different directed link prediction tasks, for which standard graph AE and VAE perform poorly. We achieve competitive results on three real-world graphs, outperforming several popular baselines.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Gravity-Inspired Graph Autoencoders for Directed Link Prediction

Salha

Limnios

Hennequin³

et al. 2019

Proceedings of the 28th ACM International Conference on Information and Knowledge Management

View full text Add to dashboard Cite

show abstract

“…If PCA does not yield a better result, it means that features are not correlated or have non-linear relationships. However, researchers often used to enable data easy to explore and visualize, in case for representation learning (RL) [28].…”

Section: Feature Extraction Techniquesmentioning

confidence: 99%

Evolutionary Computation, Optimization, and Learning Algorithms for Data Science

Mohammadi

Amini

Arabnia

2020

Advances in Intelligent Systems and Computing

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purpose. This motivates researchers to think about optimization and apply nature inspired algorithms, such as meta-heuristic and evolutionary algorithms (EAs) to solve large-scale optimization problems. Building on the strategies of these algorithms, researchers solve large-scale engineering and computational problems with innovative solutions. Although these algorithms look un-deterministic, they are robust enough to reach an optimal solution. To that end, researchers try to run their algorithms more than usually suggested, around 20 or 30 times, then they compute the mean of result and report only the average of 20 / 30 runs' result. This high number of runs becomes necessary because EAs, based on their randomness initialization, converge the best result, which would not be correct if only relying on one specific run. Certainly, researchers do not adopt evolutionary algorithms unless they face a problem which is suffering from placement in local optimal solution, rather than global optimal solution. In this chapter, we first develop a clear and formal definition of the CoD problem, next we focus on feature extraction techniques and categories, then we provide a general overview of meta-heuristic algorithms, its terminology, and desirable properties of evolutionary algorithms.A large number of engineering, science and computational problems have yet to be solved in a more computationally efficient way. One of the emerging challenges is the evolving technologies and how they enhance towards autonomy. This leads to collection of large amount of data from various sensing and measurement technologies, such as cameras, smart phones, health sensors, and environment sensors. Hence, generation, manipulation and illustration of data grow significantly. Meanwhile, data is structured purposefully through different representations, such as large-scale networks and graphs. Therefore, data plays a pivotal role in technologies by introducing several challenges: how to present, what to present, why to present. Researchers explored various approaches to implement a comprehensive solution to express their results in every particular domain, such that the solution enhances the performance and

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“…With the advancements in data production, storage and consumption, networks are becoming omnipresent; data from diverse disciplines can be represented as graph structures with prominent examples here being various social, information, technological and biological networks. Developing machine learning algorithms to analyze, predict and make sense of the structure of graph data has become a crucial task with a plethora of cross-disciplinary applications [1], [2]. The major challenge in machine learning on graph data concerns the encoding of information about its structural properties into the learning model.…”

Section: Introductionmentioning

confidence: 99%

Kernel Node Embeddings

Çelikkanat

Malliaros

2019

2019 IEEE Global Conference on Signal and Information Processing (GlobalSIP)

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Learning representations of nodes in a low dimensional space is a crucial task with many interesting applications in network analysis, including link prediction and node classification. Two popular approaches for this problem include matrix factorization and random walk-based models. In this paper, we aim to bring together the best of both worlds, towards learning latent node representations. In particular, we propose a weighted matrix factorization model which encodes random walk-based information about the nodes of the graph. The main benefit of this formulation is that it allows to utilize kernel functions on the computation of the embeddings. We perform an empirical evaluation on real-world networks, showing that the proposed model outperforms baseline node embedding algorithms in two downstream machine learning tasks.

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Network Representation Learning: A Survey

Cited by 572 publications

References 95 publications

Gravity-Inspired Graph Autoencoders for Directed Link Prediction

Gravity-Inspired Graph Autoencoders for Directed Link Prediction

Evolutionary Computation, Optimization, and Learning Algorithms for Data Science

Kernel Node Embeddings

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