Nothing Special   »   [go: up one dir, main page]

skip to main content
10.1145/2783258.2783331acmconferencesArticle/Chapter ViewAbstractPublication PageskddConference Proceedingsconference-collections
research-article

Modeling User Mobility for Location Promotion in Location-based Social Networks

Published: 10 August 2015 Publication History

Abstract

With the explosion of smartphones and social network services, location-based social networks (LBSNs) are increasingly seen as tools for businesses (e.g., restaurants, hotels) to promote their products and services. In this paper, we investigate the key techniques that can help businesses promote their locations by advertising wisely through the underlying LBSNs. In order to maximize the benefit of location promotion, we formalize it as an influence maximization problem in an LBSN, i.e., given a target location and an LBSN, which a set of k users (called seeds) should be advertised initially such that they can successfully propagate and attract most other users to visit the target location. Existing studies have proposed different ways to calculate the information propagation probability, that is how likely a user may influence another, in the settings of static social network. However, it is more challenging to derive the propagation probability in an LBSN since it is heavily affected by the target location and the user mobility, both of which are dynamic and query dependent. This paper proposes two user mobility models, namely Gaussian-based and distance-based mobility models, to capture the check-in behavior of individual LBSN user, based on which location-aware propagation probabilities can be derived respectively. Extensive experiments based on two real LBSN datasets have demonstrated the superior effectiveness of our proposals than existing static models of propagation probabilities to truly reflect the information propagation in LBSNs.

References

[1]
N. Barbieri, F. Bonchi, and G. Manco. Topic-aware social influence propagation models. In IEEE ICDM, 2012.
[2]
P. Bouros, D. Sacharidis, and N. Bikakis. Regionally influential users in location-aware social networks. In ACM GIS, 2014.
[3]
S. Chen, J. Fan, G. Li, J. Feng, K.-l. Tan, and J. Tang. Online topic-aware influence maximization. In VLDB, 2015.
[4]
W. Chen, C. Wang, and Y. Wang. Scalable influence maximization for prevalent viral marketing in large-scale social networks. In ACM KDD, 2010.
[5]
E. Cho, S. A. Myers, and J. Leskovec. Friendship and mobility: user movement in location-based social networks. In ACM KDD, 2011.
[6]
H. Gao, J. Tang, X. Hu, and H. Liu. Modeling temporal effects of human mobile behavior on location-based social networks. In ACM CIKM, 2013.
[7]
F. Giannotti, M. Nanni, and D. Pedreschi. Efficient mining of temporally annotated sequences. In SIAM SDM, 2006.
[8]
F. Giannotti, M. Nanni, F. Pinelli, and D. Pedreschi. Trajectory pattern mining. In ACM KDD, 2007.
[9]
A. Goyal, F. Bonchi, and L. V. S. Lakshmanan. Learning influence probabilities in social networks. In ACM WSDM, 2010.
[10]
A. Goyal, F. Bonchi, and L. V. S. Lakshmanan. A data-based approach to social influence maximization. In VLDB, 2012.
[11]
J. Han, M. Kamber, and J. Pei. Data Mining: Concepts and Techniques. Morgan Kaufmann, 3rd edition, 2011.
[12]
P. Kalnis, N. Mamoulis, and S. Bakiras. On discovering moving clusters in spatio-temporal data. In SSTD, 2005.
[13]
D. Kempe, J. Kleinberg, and E. Tardos. Maximizing the spread of influence through a social network. In ACM KDD, 2003.
[14]
D. Kempe, J. Kleinberg, and E. Tardos. Influential nodes in a diffusion model for social networks. In ICALP, 2005.
[15]
J. Leskovec, A. Krause, C. Guestrin, C. Faloutsos, J. VanBriesen, and N. Glance. Cost-effective outbreak detection in networks. In ACM KDD, 2007.
[16]
G. Li, S. Chen, J. Feng, K.-l. Tan, and W.-S. Li. Efficient location-aware influence maximization. In ACM SIGMOD, 2014.
[17]
M. Lichman and P. Smyth. Modeling human location data with mixtures of kernel densities. In ACM KDD, 2014.
[18]
L. Liu, J. Tang, J. Han, M. Jiang, and S. Yang. Mining topic-level influence in heterogeneous networks. In ACM CIKM, 2010.
[19]
A. Noulas, S. Scellato, C. Mascolo, and M. Pontil. An empirical study of geographic user activity patterns in foursquare. In AAAI ICWSM, 2011.
[20]
K. Saito, R. Nakano, and M. Kimura. Prediction of information diffusion probabilities for independent cascade model. In KES, 2008.
[21]
H.-H. Wu and M.-Y. Yeh. Influential nodes in one-wave diffusion model for location-based social networks. In PAKDD, 2013.
[22]
M. Ye, P. Yin, W.-C. Lee, and D.-L. Lee. Exploiting geographical influence for collaborative point-of-interest recommendation. In ACM SIGIR, 2011.
[23]
W.-Y. Zhu, W.-C. Peng, and L.-J. Chen. Exploiting mobility for location promotion in location-based social networks. In IEEE DSAA, 2014.

Cited By

View all
  • (2024)Human Mobility Prediction Based on Trend Iteration of Spectral ClusteringIEEE Transactions on Mobile Computing10.1109/TMC.2023.3288132(1-16)Online publication date: 2024
  • (2024)HyGate-GCN: Hybrid-Gate-Based Graph Convolutional Networks with dynamical ratings estimation for personalised POI recommendationExpert Systems with Applications10.1016/j.eswa.2024.125217(125217)Online publication date: Aug-2024
  • (2023)Federated Representation Learning With Data Heterogeneity for Human Mobility PredictionIEEE Transactions on Intelligent Transportation Systems10.1109/TITS.2023.325202924:6(6111-6122)Online publication date: Jun-2023
  • Show More Cited By

Recommendations

Comments

Please enable JavaScript to view thecomments powered by Disqus.

Information & Contributors

Information

Published In

cover image ACM Conferences
KDD '15: Proceedings of the 21th ACM SIGKDD International Conference on Knowledge Discovery and Data Mining
August 2015
2378 pages
ISBN:9781450336642
DOI:10.1145/2783258
Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

Sponsors

Publisher

Association for Computing Machinery

New York, NY, United States

Publication History

Published: 10 August 2015

Permissions

Request permissions for this article.

Check for updates

Author Tags

  1. check-in behavior
  2. influence maximization
  3. location-based social network
  4. propagation probability

Qualifiers

  • Research-article

Conference

KDD '15
Sponsor:

Acceptance Rates

KDD '15 Paper Acceptance Rate 160 of 819 submissions, 20%;
Overall Acceptance Rate 1,133 of 8,635 submissions, 13%

Contributors

Other Metrics

Bibliometrics & Citations

Bibliometrics

Article Metrics

  • Downloads (Last 12 months)18
  • Downloads (Last 6 weeks)5
Reflects downloads up to 22 Nov 2024

Other Metrics

Citations

Cited By

View all
  • (2024)Human Mobility Prediction Based on Trend Iteration of Spectral ClusteringIEEE Transactions on Mobile Computing10.1109/TMC.2023.3288132(1-16)Online publication date: 2024
  • (2024)HyGate-GCN: Hybrid-Gate-Based Graph Convolutional Networks with dynamical ratings estimation for personalised POI recommendationExpert Systems with Applications10.1016/j.eswa.2024.125217(125217)Online publication date: Aug-2024
  • (2023)Federated Representation Learning With Data Heterogeneity for Human Mobility PredictionIEEE Transactions on Intelligent Transportation Systems10.1109/TITS.2023.325202924:6(6111-6122)Online publication date: Jun-2023
  • (2023)Influence maximization in social networks: a survey of behaviour-aware methodsSocial Network Analysis and Mining10.1007/s13278-023-01078-913:1Online publication date: 25-Apr-2023
  • (2023)Trajectory test-train overlap in next-location prediction datasetsMachine Learning10.1007/s10994-023-06386-x112:11(4597-4634)Online publication date: 6-Sep-2023
  • (2022)Disentangling Geographical Effect for Point-of-Interest RecommendationIEEE Transactions on Knowledge and Data Engineering10.1109/TKDE.2022.3221873(1-14)Online publication date: 2022
  • (2022)Efficient Similarity-Aware Influence Maximization in Geo-Social NetworkIEEE Transactions on Knowledge and Data Engineering10.1109/TKDE.2020.304578334:10(4767-4780)Online publication date: 1-Oct-2022
  • (2022)MDLF: A Multi-View-Based Deep Learning Framework for Individual Trip Destination Prediction in Public Transportation SystemsIEEE Transactions on Intelligent Transportation Systems10.1109/TITS.2021.312334223:8(13316-13329)Online publication date: Aug-2022
  • (2022)Influence-aware Task Assignment in Spatial Crowdsourcing2022 IEEE 38th International Conference on Data Engineering (ICDE)10.1109/ICDE53745.2022.00206(2141-2153)Online publication date: May-2022
  • (2022)Reachability-Driven Influence Maximization in Time-dependent Road-social Networks2022 IEEE 38th International Conference on Data Engineering (ICDE)10.1109/ICDE53745.2022.00032(367-379)Online publication date: May-2022
  • Show More Cited By

View Options

Login options

View options

PDF

View or Download as a PDF file.

PDF

eReader

View online with eReader.

eReader

Media

Figures

Other

Tables

Share

Share

Share this Publication link

Share on social media