research-article

Who Will Share My Image?: Predicting the Content Diffusion Path in Online Social Networks

Authors:

Krishna Kumar Singh,

Chen-Nee Chuah,

Yong Jae LeeAuthors Info & Claims

WSDM '18: Proceedings of the Eleventh ACM International Conference on Web Search and Data Mining

Pages 252 - 260

https://doi.org/10.1145/3159652.3159705

Published: 02 February 2018 Publication History

Abstract

Content popularity prediction has been extensively studied due to its importance and interest for both users and hosts of social media sites like Facebook, Instagram, Twitter, and Pinterest. However, existing work mainly focuses on modeling popularity using a single metric such as the total number of likes or shares. In this work, we propose Diffusion-LSTM, a memory-based deep recurrent network that learns to recursively predict the entire diffusion path of an image through a social network. By combining user social features and image features, and encoding the diffusion path taken thus far with an explicit memory cell, our model predicts the diffusion path of an image more accurately compared to alternate baselines that either encode only image or social features, or lack memory. By mapping individual users to user prototypes, our model can generalize to new users not seen during training. Finally, we demonstrate our model»s capability of generating diffusion trees, and show that the generated trees closely resemble ground-truth trees.

References

[1]

N. Agarwal, M. Galan, H. Liu, and S. Subramanya. 2010. WisColl: Collective Wisdom Based Blog Clustering. Information Sciences.

Digital Library

[2]

L. Backstrom and J. Leskovec. 2011. Supervised Random Walks: Predicting and Recommending Links in Social Networks WSDM.

Digital Library

[3]

E. Bakshy, I. Rosenn, C. Marlow, and L. Adamic. 2012. The Role of Social Networks in Information Diffusion WWW.

Digital Library

[4]

Y. Bengio, P. Simard, and P. Frasconi. 1994. Learning Long-term Dependencies with Gradient Descent is Difficult IEEE Transactions on Neural Networks.

Digital Library

[5]

H. Borges, A. Hora, and M. T. Valente. 2016. Predicting the Popularity of Github Repositories. PROMISE.

Digital Library

[6]

X. Chen and C. Lawrence Zitnicki. 2015. Mind's Eye: A Recurrent Visual Representation for Image Caption Generation CVPR.

[7]

J. Cheng, L. Adamic, P. Dow, J. Kleinberg, and J. Leskovec. 2014. Can cascades be predicted?. In WWW.

Digital Library

[8]

A. Deza and D. Parikh. 2015. Understanding Image Virality. In CVPR.

[9]

J. Donahue, L. Anne Hendricks, S. Guadarrama, M. Rohrbach, S. Venugopalan, K. Saenko, and T. Darrell. 2015. Long-term Recurrent Convolutional Networks for Visual Recognition and Description CVPR.

[10]

F. Gelli, T. Uricchio, M. Bertini, A. Del Bimbo, and S. F. Chang. 2015. Image Popularity Prediction in Social Media Using Sentiment and Context Features ACM Multimedia.

Digital Library

[11]

F. A. Gers, J. Schmidhuber, and F. Cummins. 2000. Learning to Forget: Continual Prediction with LSTM Neural Computation.

Digital Library

[12]

F. A. Gers, N. N. Schraudolph, and J. Schmidhuber. 2002. Learning Precise Timing with LSTM Recurrent Networks JMLR.

Digital Library

[13]

A. Grover and J. Leskovec. 2016. Node2vec: Scalable Feature Learning for Networks. KDD.

Digital Library

[14]

M. Guerini, J. Staiano, and D. Albanese. 2013. Exploring image virality in google plus. In SocialCom.

Digital Library

[15]

J. Han, D. Choi, A. Choi, J. Choi, T. Chung, T. T. Kwon, J. Y. Rha, and C. H. Chuah. 2015. Sharing Topics in Pinterest: Understanding Content Creation and Diffusion Behaviors COSN.

Digital Library

[16]

S. Hochreiter. 1998. The Vanishing Gradient Problem During Learning Recurrent Neural Nets and Problem Solutions IJUFKS.

Digital Library

[17]

S. Hochreiter and J. Schmidhuber. 1997. Long short-term memory. In Neural Computation.

[18]

L. Hong, O. Dan, and B. D. Davison. 2011. Predicting Popular Messages in Twitter. In WWW.

Digital Library

[19]

B. A. Huberman, D. M. Romero, and F. Wu. 2008. Social Networks that Matter: Twitter Under the Microscope arXiv:0812.1045v1.

[20]

J. Johnson, A. Karpathy, and L. Fei-Fei. 2016. Densecap: Fully convolutional localization networks for dense captioning CVPR.

[21]

A. Karpathy and L. Fei-Fei. 2015. Deep Visual-semantic Alignments for Generating Image Descriptions CVPR.

[22]

A. Khosla, A. Das Sarma, and R. Hamid. 2014. What Makes an Image Popular?. In WWW.

Digital Library

[23]

M. Kimura and K. Saito. 2006. Tractable Models for Information Diffusion in Social Networks European Conference on Principles of Data Mining and Knowledge Discovery.

[24]

A. Krizhevsky, I. Sutskever, and G. Hinton. 2012. Imagenet Classification with Deep Convolutional Neural Networks NIPS.

Digital Library

[25]

A. Kupavskii, A. Umnov, G. Gusev, and P. Serdyukov. 2013. Predicting the Audience Size of a Tweet. In AAAI.

[26]

H. Li, X. Ma, F. Wang, J. Liu, and K. Xu. 2013. On Popularity Prediction of Videos Shared in Online Social Networks CIKM.

Digital Library

[27]

D. Liben-Nowell and J. Kleinberg. 2007. The link-prediction problem for social networks. JASIST.

Digital Library

[28]

Z. Ma, A. Sun, and G. Cong. 2013. On Predicting the Popularity of Newly Emerging Hashtags in Twitter JASIST.

[29]

T. Mikolov, M. Karafiát, L. Burget, J. Cernocký, and S. Khudanpur. 2010. Recurrent neural network based language model. In INTERSPEECH.

[30]

S. Scellato, A. Noulas, and C. Mascolo. 2011. Exploiting place features in link prediction on location-based social networks KDD.

Digital Library

[31]

K. Simonyan and A. Zisserman. 2015. Very Deep Convolutional Networks for Large-scale Image Recognition ICLR.

[32]

K. S. Tai, R. Socher, and C. D. Manning. 2015. Improved Semantic Representations from Tree-structured Long Short-term Memory Networks ACL.

[33]

L. Totti, F. Costa, S. Avila, E. Valle, W. Meira Jr, and V. Almeida. 2014. The Impact of Visual Attributes on Online Image Diffusion WebSci.

Digital Library

[34]

O. Vinyals, A. Toshev, S. Bengio, and D. Erhan. 2015. Show and Tell: A Neural Image Caption Generator. CVPR.

[35]

D. Wang, D. Pedreschi, C. Song, F. Giannotti, and A. L. Barabasi. 2011. Human Mobility, Social Ties, and Link Prediction. KDD.

Digital Library

[36]

L. Weng, F. Menczer, and Y. Y. Ahn. 2013. Virality Prediction and Community Structure in Social Networks Scientific Reports.

[37]

S. H. Yang and H. Zha. 2013. Mixture of Mutually Exciting Processes for Viral Diffusion ICML.

Digital Library

[38]

X. Zhang, L. Lu, and M. Lapata. 2016. Top-down Tree Long Short-term Memory Networks. In NAACL.

[39]

X. Zhu, P. Sobihani, and H. Guo. 2015. Long Short-term Memory Over Recursive Structures. ICML.

Digital Library

Cited By

Santana JSantana MSampaio PBrito K(2024)Towards a Methodology for Analyzing Visual Elements in Social Media Posts of PoliticiansProceedings of the 17th International Conference on Theory and Practice of Electronic Governance10.1145/3680127.3680218(366-373)Online publication date: 1-Oct-2024
https://dl.acm.org/doi/10.1145/3680127.3680218
Wang GLi WBai QLai E(2024)Maximizing Social Influence With Minimum Information AlterationIEEE Transactions on Emerging Topics in Computing10.1109/TETC.2023.329238412:2(419-431)Online publication date: Apr-2024
https://doi.org/10.1109/TETC.2023.3292384
Li HXia CWang TZhao H(2023)CHESS: Learning User Correlation from Semantic-related Cascades for Diffusion Prediction2023 IEEE Smart World Congress (SWC)10.1109/SWC57546.2023.10448706(1-9)Online publication date: 28-Aug-2023
https://doi.org/10.1109/SWC57546.2023.10448706
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Who Will Share My Image?: Predicting the Content Diffusion Path in Online Social Networks

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cover image ACM Conferences

WSDM '18: Proceedings of the Eleventh ACM International Conference on Web Search and Data Mining

February 2018

821 pages

ISBN:9781450355810

DOI:10.1145/3159652

General Chairs:
Yi Chang
Jilin University, Huawei Inc.
,
Chengxiang Zhai
University of Illinois Urbana-Champaign
,
Program Chairs:
Yan Liu
University of Southern California
,
Yoelle Maarek
Amazon

Copyright © 2018 ACM.

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Published: 02 February 2018

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NVIDIA
Hanyang University

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WSDM 2018

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WSDM 2018: The Eleventh ACM International Conference on Web Search and Data Mining

February 5 - 9, 2018

CA, Marina Del Rey, USA

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WSDM '18 Paper Acceptance Rate 81 of 514 submissions, 16%;

Overall Acceptance Rate 498 of 2,863 submissions, 17%

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Cited By

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https://dl.acm.org/doi/10.1145/3680127.3680218
Wang GLi WBai QLai E(2024)Maximizing Social Influence With Minimum Information AlterationIEEE Transactions on Emerging Topics in Computing10.1109/TETC.2023.329238412:2(419-431)Online publication date: Apr-2024
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Li HXia CWang TZhao H(2023)CHESS: Learning User Correlation from Semantic-related Cascades for Diffusion Prediction2023 IEEE Smart World Congress (SWC)10.1109/SWC57546.2023.10448706(1-9)Online publication date: 28-Aug-2023
https://doi.org/10.1109/SWC57546.2023.10448706
Li HXia CWang TZhao H(2022)CRCS: Learning Synergistic Cascade Correlation for Microscopic Cascade Prediction2022 IEEE Smartworld, Ubiquitous Intelligence & Computing, Scalable Computing & Communications, Digital Twin, Privacy Computing, Metaverse, Autonomous & Trusted Vehicles (SmartWorld/UIC/ScalCom/DigitalTwin/PriComp/Meta)10.1109/SmartWorld-UIC-ATC-ScalCom-DigitalTwin-PriComp-Metaverse56740.2022.00165(1152-1159)Online publication date: Dec-2022
https://doi.org/10.1109/SmartWorld-UIC-ATC-ScalCom-DigitalTwin-PriComp-Metaverse56740.2022.00165
Gomes JBernardino Hde Souza JRajabi E(2022)Indexing, enriching, and understanding Brazilian missing person cases from data of distributed repositories on the webAI & SOCIETY10.1007/s00146-022-01456-538:2(565-579)Online publication date: 19-May-2022
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Wang HYang CShi CDemartini GZuccon GCulpepper JHuang ZTong H(2021)Neural Information Diffusion Prediction with Topic-Aware Attention NetworkProceedings of the 30th ACM International Conference on Information & Knowledge Management10.1145/3459637.3482374(1899-1908)Online publication date: 26-Oct-2021
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Bohra NBhatnagar V(2021)Group level social media popularity prediction by MRGB and Adam optimizationJournal of Combinatorial Optimization10.1007/s10878-020-00684-z41:2(328-347)Online publication date: 3-Jan-2021
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