Community aware random walk for network embedding

Keikha, Mohammad Mehdi; Rahgozar, Maseud; Asadpour, Masoud

doi:10.1016/j.knosys.2018.02.028

Cited by 70 publications

(33 citation statements)

References 20 publications

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“…MNMF [10] successfully saves the community structure in the generated node representations and improves the quality of node representation vectors, it preserves the first and second-order similarities of nodes with Non-negative Matrix Factorization(NMF), models community structure with modularity maximization. CARE [11] uses community attributes to capture more network structure information. It designs a community-aware random walk strategy and uses the Skip-gram model to learn the node representations.…”

Section: Related Workmentioning

confidence: 99%

“…For example, MNMF [10] preserves the community structure of the network while considering the proximity of nodes. CARE [11] designs the community-aware random walks when learning the node representation vectors. Based on Expansion Sampling(XS) strategy [12] [13] [14], SENE [15] saves the mesoscopic community information in the learned node representation vectors.…”

Section: Introductionmentioning

confidence: 99%

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The Network Representation Learning Algorithm Based on Semi-Supervised Random Walk

Dong

et al. 2020

IEEE Access

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Section: Related Workmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The Network Representation Learning Algorithm Based on Semi-Supervised Random Walk

Dong

et al. 2020

IEEE Access

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“…The Hadamard operator is the best operator for edge feature learning from user feature vectors [24], [26]. An edge feature vector indicates that the source and destination nodes of a link are similar based on their structural and content features.…”

Section: Figure 3-content Feature Vector Learning In Deeplinkmentioning

confidence: 99%

DeepLink: A novel link prediction framework based on deep learning

Keikha

Rahgozar

Asadpour

2019

Journal of Information Science

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Recently, link prediction has attracted more attentions from various disciplines such as computer science, bioinformatics and economics. In this problem, unknown links between nodes are discovered based on numerous information such as network topology, profile information and user generated contents. Most of the previous researchers have focused on the structural features of the networks. While the recent researches indicate that contextual information can change the network topology. Although, there are number of valuable researches which combine structural and content information, but they face with the scalability issue due to feature engineering. Because, majority of the extracted features are obtained by a supervised or semi supervised algorithm. Moreover, the existing features are not general enough to indicate good performance on different networks with heterogeneous structures. Besides, most of the previous researches are presented for undirected and unweighted networks.In this paper, a novel link prediction framework called "DeepLink" is presented based on deep learning techniques. In contrast to the previous researches which fail to automatically extract best features for the link prediction, deep learning reduces the manual feature engineering. In this framework, both the structural and content information of the nodes are employed. The framework can use different structural feature vectors, which are prepared by various link prediction methods. It considers all proximity orders that are presented in a network during the structural feature learning. We have evaluated the performance of DeepLink on two real social network datasets including Telegram and irBlogs. On both datasets, the proposed framework outperforms several structural and hybrid approaches for link prediction problem.

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“…In machine learning applications, the traditional single label classification (SLC) problem has been explored substantially. However, more recently, the multi-label classification (MLC) problem has attracted increasing research interest because of its wide range of applications, such as text classification [ 1 , 2 ], social network analysis [ 3 ], gene function classification [ 4 ], and image/video annotation [ 5 ]. With SLC, one instance only belongs to one category, whereas with MLC, it can be allocated to multiple categories simultaneously.…”

Section: Introductionmentioning

confidence: 99%

Partial Classifier Chains with Feature Selection by Exploiting Label Correlation in Multi-Label Classification

Wang

Wan

et al. 2020

Entropy

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Multi-label classification (MLC) is a supervised learning problem where an object is naturally associated with multiple concepts because it can be described from various dimensions. How to exploit the resulting label correlations is the key issue in MLC problems. The classifier chain (CC) is a well-known MLC approach that can learn complex coupling relationships between labels. CC suffers from two obvious drawbacks: (1) label ordering is decided at random although it usually has a strong effect on predictive performance; (2) all the labels are inserted into the chain, although some of them may carry irrelevant information that discriminates against the others. In this work, we propose a partial classifier chain method with feature selection (PCC-FS) that exploits the label correlation between label and feature spaces and thus solves the two previously mentioned problems simultaneously. In the PCC-FS algorithm, feature selection is performed by learning the covariance between feature set and label set, thus eliminating the irrelevant features that can diminish classification performance. Couplings in the label set are extracted, and the coupled labels of each label are inserted simultaneously into the chain structure to execute the training and prediction activities. The experimental results from five metrics demonstrate that, in comparison to eight state-of-the-art MLC algorithms, the proposed method is a significant improvement on existing multi-label classification.

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Community aware random walk for network embedding

Cited by 70 publications

References 20 publications

The Network Representation Learning Algorithm Based on Semi-Supervised Random Walk

The Network Representation Learning Algorithm Based on Semi-Supervised Random Walk

DeepLink: A novel link prediction framework based on deep learning

Partial Classifier Chains with Feature Selection by Exploiting Label Correlation in Multi-Label Classification

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