research-article

Topic-Aware Physical Activity Propagation with Temporal Dynamics in a Health Social Network

Authors:

Javid Ebrahimi,

Brigitte Piniewski,

Dejing DouAuthors Info & Claims

ACM Transactions on Intelligent Systems and Technology (TIST), Volume 8, Issue 1

Article No.: 2, Pages 1 - 20

https://doi.org/10.1145/2873066

Published: 23 August 2016 Publication History

Abstract

Modeling physical activity propagation, such as activity level and intensity, is a key to preventing obesity from cascading through communities, and to helping spread wellness and healthy behavior in a social network. However, there have not been enough scientific and quantitative studies to elucidate how social communication may deliver physical activity interventions. In this work, we introduce a novel model named Topic-aware Community-level Physical Activity Propagation with Temporal Dynamics (TCPT) to analyze physical activity propagation and social influence at different granularities (i.e., individual level and community level). Given a social network, the TCPT model first integrates the correlations between the content of social communication, social influences, and temporal dynamics. Then, a hierarchical approach is utilized to detect a set of communities and their reciprocal influence strength of physical activities. The experimental evaluation shows not only the effectiveness of our approach but also the correlation of the detected communities with various health outcome measures. Our promising results pave a way for knowledge discovery in health social networks.

References

[1]

A. Bauman, T. Armstrong, J. Davies, N. Owen, W. Brown, B. Bellew, and P. Vita. 2003. Trends in physical activity participation and the impact of integrated campaigns among Australian adults, 1997--99. Australian and New Zealand Journal of Public Health 27, 1, 76--9.

[2]

D. M. Blei, A. Y. Ng, and M. I. Jordan. 2003. Latent Dirichlet allocation. Journal of Machine Learning Research 3, 993--1022.

Digital Library

[3]

N. A. Christakis and J. H. Fowler. 2007. The spread of obesity in a large social network over 32 years. New England Journal of Medicine 357, 370--9.

[4]

P. Domingos and M. Richardson. 2001. Mining the network value of customers. In Proceedings of KDD’01. 57--66.

Digital Library

[5]

J. H. Fowler and N. A. Christakis. 2009. Dynamic spread of happiness in a large social network: longitudinal analysis of the Framingham Heart Study social network. BMJ: British Medical Journal 23--27.

[6]

M. Gomez-Rodriguez, D. Balduzzi, and B. Schölkopf. 2011. Uncovering the temporal dynamics of diffusion networks. In ICML’11.

[7]

M. Gomez-Rodriguez, J. Leskovec, D. Balduzzi, and B. Schölkopf. 2014. Uncovering the structure and temporal dynamics of information propagation. Network Science 2, 1, 26--65.

[8]

A. Goyal, F. Bonchi, and L. V. S. Lakshmanan. 2010. Learning influence probabilities in social networks. In Proceedings of WSDM’10. 241--250.

Digital Library

[9]

G. Heinrich. 2004. Parameter Estimation for Text Analysis. Technical Report. vsonix GmbH and University of Leipzig, Leipzig, Germany.

[10]

Internet World Stats. 2016. Internet Users in the World by Regions November 2015. Retrieved June 29, 2016 from http://www.internetworldstats.com/stats.htm.

[11]

G. Karypis and V. Kumar. 1998. A fast and high quality multilevel scheme for partitioning irregular graphs. SIAM Journal on Scientific Computing 20, 1, 359--392.

Digital Library

[12]

D. Kempe, J. M. Kleinberg, and E. Tardos. 2003. Maximizing the spread of influence through a social network. In Proceedings of KDD’03. 137--146.

Digital Library

[13]

D. Kil, F. Shin, B. Piniewski, J. Hahn, and K. Chan. 2012. Impacts of social health data on predicting weight loss and engagement. In O’Reilly StrataRx Conference, San Francisco, CA.

[14]

B. H. Marcus, C. R. Nigg, D. Riebe, and L. H. Forsyth. 2000. Interactive communication strategies: Implications for population-based physical activity promotion. American Journal of Preventive Medicine 19, 2, 121--6.

[15]

A. Marshall, E. G. Eakin, E. R. Leslie, and N. Owen. 2005. Exploring the feasibility and acceptability of using Internet technology to promote physical activity within a defined community. Health Promotion Journal of Australia 2005, 16, 82--4.

[16]

M. Mathioudakis, F. Bonchi, C. Castillo, A. Gionis, and A. Ukkonen. 2011. Sparsification of influence networks. In Proceedings of KDD’11. 529--537.

Digital Library

[17]

S. C. Mednick, N. A. Christakis, and J. H. Fowler. 2010. The spread of sleep loss influences drug use in adolescent social networks. PloS One 5, 3, e9775.

[18]

Y. Mehmood, Nicola Barbieri, F. Bonchi, and A. Ukkonen. 2013. CSI: Community-level social influence analysis. In Proceedings of ECML-PKDD’13. 48--63.

[19]

S. Navlakha, R. Rastogi, and N. Shrivastava. 2008. Graph summarization with bounded error. In Proceedings of SIGMOD’08. 419--432.

Digital Library

[20]

R. R. Pate, M. Pratt, S. N. Blair, et al. 1995. Physical activity and public health. A recommendation from the Centers for Disease Control and Prevention and the American College of Sports Medicine. Journal of the American Medical Association 273, 5, 402--7.

[21]

N. Phan, D. Dou, X. Xiao, B. Piniewski, and D. Kil. 2014. Analysis of physical activity propagation in a health social network. In Proceedings of CIKM’14. 1329--1338.

Digital Library

[22]

N. Phan, J. Ebrahimi, D. Kil, B. Piniewski, and D. Dou. 2016. Topic-aware physical activity propagation in a health social network. IEEE Intelligent Systems 31, 1, 5--14.

Digital Library

[23]

J. Rissanen. 1983. A universal prior for integers and estimation by minimum description length. The Annals of Statistics 14, 5, 416--431.

[24]

L.M. Ritterband, L. A. Gonder-Frederick, D. J. Cox, A. D. Clifton, R. W. West, and S. M. Borowitz. 2003. Internet interventions: In review, in use, and into the future. Professional Psychology: Research and Practice 34, 527--34.

[25]

J. N. Rosenquist, J. Murabito, J. H. Fowler, and N. A. Christakis. 2010. The spread of alcohol consumption behavior in a large social network. Annals of Internal Medicine 152, 7, 426--433.

[26]

K. Saito, R. Nakano, and M. Kimura. 2008. Prediction of information diffusion probabilities for independent cascade model. In Proceedings of KES’08. 67--75.

Digital Library

[27]

G. Schwarz. 1978. Estimating the dimension of a model. The Annals of Statistics 6, 2, 461--464.

[28]

Y. Shen, R. Jin, D. Dou, N. Chowdhury, J. Sun, B. Piniewski, and D. Kil. 2012. Socialized Gaussian process model for human behavior prediction in a health social network. In Proceedings of ICDM’12. 1110--1115.

Digital Library

[29]

Y. Tian, R. A. Hankins, and J. M. Patel. 2008. Efficient aggregation for graph summarization. In Proceedings of SIGMOD’08. 567--580.

Digital Library

[30]

U.S. Department of Health & Human Services. 1996. Physical activity and health: A report of the surgeon general. Atlanta GA: U.S. Department of Health and Human Services, Centers for Disease Control and Prevention, National Center for Chronic Disease Prevention and Health Promotion.

[31]

C. Vandelanotte, K. M. Spathonis, E. G. Eakin, and N. Owen. 2007. Website-delivered physical activity interventions: A review of the literature. American Journal of Preventive Medicine 33, 1, 54--64.

[32]

N. Zhang, Y. Tian, and J. M. Patel. 2010. Discovery-driven graph summarization. In Proceedings of ICDE’10. 880--891.

Cited By

Gupta AZhang Z(2022)Neural Topic Modeling via Discrete Variational InferenceACM Transactions on Intelligent Systems and Technology10.1145/357050914:2(1-33)Online publication date: 25-Nov-2022
https://dl.acm.org/doi/10.1145/3570509
Wang SLi LYang CHuang Q(2019)Regularized topic-aware latent influence propagation in dynamic relational networksGeoinformatica10.1007/s10707-019-00357-y23:3(329-352)Online publication date: 1-Jul-2019
https://dl.acm.org/doi/10.1007/s10707-019-00357-y
Amimeur APhan NDou DKil DPiniewski B(2016)Interaction Network Representations for Human Behavior Prediction2016 15th IEEE International Conference on Machine Learning and Applications (ICMLA)10.1109/ICMLA.2016.0023(87-93)Online publication date: Dec-2016
https://doi.org/10.1109/ICMLA.2016.0023

Index Terms

Topic-Aware Physical Activity Propagation with Temporal Dynamics in a Health Social Network

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Published In

cover image ACM Transactions on Intelligent Systems and Technology

ACM Transactions on Intelligent Systems and Technology Volume 8, Issue 1

January 2017

363 pages

ISSN:2157-6904

EISSN:2157-6912

DOI:10.1145/2973184

Editor:
Yu Zheng
Microsoft Research, China

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Copyright © 2016 ACM.

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 23 August 2016

Accepted: 01 December 2015

Revised: 01 November 2015

Received: 01 July 2015

Published in TIST Volume 8, Issue 1

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Cited By

Gupta AZhang Z(2022)Neural Topic Modeling via Discrete Variational InferenceACM Transactions on Intelligent Systems and Technology10.1145/357050914:2(1-33)Online publication date: 25-Nov-2022
https://dl.acm.org/doi/10.1145/3570509
Wang SLi LYang CHuang Q(2019)Regularized topic-aware latent influence propagation in dynamic relational networksGeoinformatica10.1007/s10707-019-00357-y23:3(329-352)Online publication date: 1-Jul-2019
https://dl.acm.org/doi/10.1007/s10707-019-00357-y
Amimeur APhan NDou DKil DPiniewski B(2016)Interaction Network Representations for Human Behavior Prediction2016 15th IEEE International Conference on Machine Learning and Applications (ICMLA)10.1109/ICMLA.2016.0023(87-93)Online publication date: Dec-2016
https://doi.org/10.1109/ICMLA.2016.0023

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