research-article

Build your own music recommender by modeling internet radio streams

Authors:

Natalie Aizenberg,

Oren SomekhAuthors Info & Claims

WWW '12: Proceedings of the 21st international conference on World Wide Web

Pages 1 - 10

https://doi.org/10.1145/2187836.2187838

Published: 16 April 2012 Publication History

Abstract

In the Internet music scene, where recommendation technology is key for navigating huge collections, large market players enjoy a considerable advantage. Accessing a wider pool of user feedback leads to an increasingly more accurate analysis of user tastes, effectively creating a "rich get richer" effect. This work aims at significantly lowering the entry barrier for creating music recommenders, through a paradigm coupling a public data source and a new collaborative filtering (CF) model. We claim that Internet radio stations form a readily available resource of abundant fresh human signals on music through their playlists, which are essentially cohesive sets of related tracks. In a way, our models rely on the knowledge of a diverse group of experts in lieu of the commonly used wisdom of crowds. Over several weeks, we aggregated publicly available playlists of thousands of Internet radio stations, resulting in a dataset encompassing millions of plays, and hundreds of thousands of tracks and artists. This provides the large scale ground data necessary to mitigate the cold start problem of new items at both mature and emerging services.

Furthermore, we developed a new probabilistic CF model, tailored to the Internet radio resource. The success of the model was empirically validated on the collected dataset. Moreover, we tested the model at a cross-source transfer learning manner -- the same model trained on the Internet radio data was used to predict behavior of Yahoo! Music users. This demonstrates the ability to tap the Internet radio signals in other music recommendation setups. Based on encouraging empirical results, our hope is that the proposed paradigm will make quality music recommendation accessible to all interested parties in the community.

References

[1]

D. Agarwal and B.-C. Chen. Regression-based latent factor models. InKDD, pages 19--28, 2009.

Digital Library

[2]

X. Amatriain, J. Bonada, Àlex Loscos, J. L. Arcos, and V. Verfaille. Content-based transformations. Journal of New Music Research, 32:2003, 2003.

[3]

Y. Bengio and J.-S. Senécal. Quick training of probabilistic neural nets by sampling. In Proc. 9th International Workshop on Artificial Intelligence and Statistics (AISTATS'03), 2003.

[4]

M. Castelluccio. The music genome project. Strategic Finance, 88:57--58, 2006.

[5]

B. Fields, C. Rhodes, and M. d'Inverno. Using song social tags and topic models to describe and compare playlists. Barcelona, September 2010. ACM.

[6]

T. Hofmann. Latent semantic models for collaborative filtering.ACM Trans. Inf. Syst., 22:89-115, January 2004.

Digital Library

[7]

Y. Hu, Y. Koren, and C. Volinsky. Collaborative filtering for implicit feedback datasets. In ICDM, pages 263--272, 2008.

Digital Library

[8]

M. Jamali and M. Ester. A matrix factorization technique with trust propagation for recommendation in social networks. In RecSys, pages 135--142, 2010.

Digital Library

[9]

N. Koenigstein, G. Dror, and Y. Koren. Yahoo! music recommendations: modeling music ratings with temporal dynamics and item taxonomy. In RecSys, pages 165--172, 2011.

Digital Library

[10]

Y. Koren. Factorization meets the neighborhood: a multifaceted collaborative filtering model. In KDD, pages 426--434, 2008.

Digital Library

[11]

Y. Koren. Collaborative filtering with temporal dynamics. In KDD, pages 447--456, 2009.

Digital Library

[12]

Y. Koren, R. M. Bell, and C. Volinsky. Matrix factorization techniques for recommender systems. IEEE Computer, 42(8):30--37, 2009.

Digital Library

[13]

P. Lamere. Social tagging and music information retrieval. Journal of New Music Research, 37(2):101--114, 2008.

[14]

B. Li, Q. Yang, and X. Xue. Transfer learning for collaborative filtering via a rating-matrix generative model. In ICML, page 78, 2009.

Digital Library

[15]

A. Nanopoulos, D. Rafailidis, P. Symeonidis, and Y. Manolopoulos. Musicbox: Personalized music recommendation based on cubic analysis of social tags.IEEE Trans. on Audio, Speech and Language Processing, 18(2):407--412, 2010.

Digital Library

[16]

R. Pan, Y. Zhou, B. Cao, N. N. Liu, R. M. Lukose, M. Scholz, and Q. Yang. One-class collaborative filtering. In ICDM, pages 502--511, 2008.

Digital Library

[17]

W. Pan, E. W. Xiang, N. N. Liu, and Q. Yang. Transfer learning in collaborative filtering for sparsity reduction. In AAAI, 2010.

Digital Library

[18]

A. Paterek. Improving regularized singular value decomposition for collaborative filtering.Proceedings of KDD Cup and Workshop, 2007.

[19]

R. Ragno, C. J. C. Burges, and C. Herley. Inferring similarity between music objects with application to playlist generation. In Proc. 7th ACM SIGMM int. workshop on Multimedia information retrieval, pages 73--80, 2005.

Digital Library

[20]

S. Rendle, C. Freudenthaler, Z. Gantner, and S.-T. Lars. Bpr: Bayesian personalized ranking from implicit feedback. In Proc. 25th Conference on Uncertainty in Artificial Intelligence, UAI '09, pages 452--461, 2009.

Digital Library

[21]

S. Rendle, L. B. Marinho, A. Nanopoulos, and L. Schmidt-Thieme. Learning optimal ranking with tensor factorization for tag recommendation. In KDD, pages 727--736, 2009.

Digital Library

[22]

F. Ricci, L. Rokach, B. Shapira, and P. B. Kantor, editors. Recommender Systems Handbook. Springer, 2011.

[23]

R. Salakhutdinov and A. Mnih. Bayesian probabilistic matrix factorization using markov chain monte carlo. In ICML, pages 880--887, 2008.

Digital Library

[24]

R. Salakhutdinov, A. Mnih, and G. E. Hinton. Restricted boltzmann machines for collaborative filtering. In ICML, pages 791--798, 2007.

Digital Library

[25]

M. Schedl and P. Knees. Context-based Music Similarity Estimation. In Proc. 3rd International Workshop on Learning the Semantics of Audio Signals (LSAS 2009), 2009.

[26]

M. Slaney. Web-scale multimedia analysis: Does content matter? IEEE MultiMedia, 18(2):12--15, 2011.

Digital Library

[27]

Y. Zhang, B. Cao, and D.-Y. Yeung. Multi-domain collaborative filtering. InProc26th Conference Annual Conference on Uncertainty in Artificial Intelligence (UAI-10), pages 725--732, 2010.

[28]

E. Zheleva, J. Guiver, E. Mendes Rodrigues, and N. Milic-Frayling. Statistical models of music-listening sessions in social media. In Proc. 19th int. conference on World wide web, WWW '10, pages 1019--1028, 2010.

Digital Library

Cited By

Gabbolini GBridge D(2024)Surveying More Than Two Decades of Music Information Retrieval Research on PlaylistsACM Transactions on Intelligent Systems and Technology10.1145/368839815:6(1-68)Online publication date: 12-Aug-2024
https://dl.acm.org/doi/10.1145/3688398
Shtoff AViderman MHaramaty-Krasne NSomekh ORaviv ABan T(2024)Low Rank Field-Weighted Factorization Machines for Low Latency Item RecommendationProceedings of the 18th ACM Conference on Recommender Systems10.1145/3640457.3688097(238-246)Online publication date: 8-Oct-2024
https://dl.acm.org/doi/10.1145/3640457.3688097
Liu KChen YTang JHuang HLiu L(2023)Self-Attentive Subset Learning over a Set-Based Preference in RecommendationApplied Sciences10.3390/app1303168313:3(1683)Online publication date: 28-Jan-2023
https://doi.org/10.3390/app13031683
Show More Cited By

Index Terms

Build your own music recommender by modeling internet radio streams
1. Information systems
  1. Information systems applications
    1. Data mining

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Published In

cover image ACM Other conferences

WWW '12: Proceedings of the 21st international conference on World Wide Web

April 2012

1078 pages

ISBN:9781450312295

DOI:10.1145/2187836

General Chairs:
Alain Mille
Université de Lyon, France
,
Fabien Gandon
INRIA, France
,
Jacques Misselis
HP, France
,
Program Chairs:
Michael Rabinovich
Case Western Reserve University, USA
,
Steffen Staab
University of Koblenz-Landau, Germany

Copyright © 2012 ACM.

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]

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Univ. de Lyon: Universite de Lyon

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SIGWEB: ACM Special Interest Group on Hypertext, Hypermedia, and Web

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 16 April 2012

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WWW 2012

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Univ. de Lyon

WWW 2012: 21st World Wide Web Conference 2012

April 16 - 20, 2012

Lyon, France

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Overall Acceptance Rate 1,899 of 8,196 submissions, 23%

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Cited By

Gabbolini GBridge D(2024)Surveying More Than Two Decades of Music Information Retrieval Research on PlaylistsACM Transactions on Intelligent Systems and Technology10.1145/368839815:6(1-68)Online publication date: 12-Aug-2024
https://dl.acm.org/doi/10.1145/3688398
Shtoff AViderman MHaramaty-Krasne NSomekh ORaviv ABan T(2024)Low Rank Field-Weighted Factorization Machines for Low Latency Item RecommendationProceedings of the 18th ACM Conference on Recommender Systems10.1145/3640457.3688097(238-246)Online publication date: 8-Oct-2024
https://dl.acm.org/doi/10.1145/3640457.3688097
Liu KChen YTang JHuang HLiu L(2023)Self-Attentive Subset Learning over a Set-Based Preference in RecommendationApplied Sciences10.3390/app1303168313:3(1683)Online publication date: 28-Jan-2023
https://doi.org/10.3390/app13031683
Abutbul EKaplan YKrasne NSomekh ODavid ODuvdevany OSegal E(2023)Audience Prospecting for Dynamic-Product-Ads in Native Advertising2023 IEEE International Conference on Big Data (BigData)10.1109/BigData59044.2023.10386796(1571-1580)Online publication date: 15-Dec-2023
https://doi.org/10.1109/BigData59044.2023.10386796
Rehman Khan HLim CAhmed MTan KBin Mokhtar M(2021)Systematic Review of Contextual Suggestion and Recommendation Systems for Sustainable e-TourismSustainability10.3390/su1315814113:15(8141)Online publication date: 21-Jul-2021
https://doi.org/10.3390/su13158141
Kaplan YKrasne NShtoff ASomekh ODemartini GZuccon GCulpepper JHuang ZTong H(2021)Unbiased Filtering of Accidental Clicks in Verizon Media Native AdvertisingProceedings of the 30th ACM International Conference on Information & Knowledge Management10.1145/3459637.3481958(3878-3887)Online publication date: 26-Oct-2021
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Kaplan YKoren YLeibovits RSomekh O(2021)Dynamic Length Factorization Machines for CTR Prediction2021 IEEE International Conference on Big Data (Big Data)10.1109/BigData52589.2021.9671557(1950-1959)Online publication date: 15-Dec-2021
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Vidmar Horvat K(2021)Conspiracy Theories and the Crisis of the Public Sphere: COVID-19 in SloveniaJavnost - The Public10.1080/13183222.2021.192152228:2(219-235)Online publication date: 8-Jun-2021
https://doi.org/10.1080/13183222.2021.1921522
Rutkowski TRutkowski T(2021)IntroductionExplainable Artificial Intelligence Based on Neuro-Fuzzy Modeling with Applications in Finance10.1007/978-3-030-75521-8_1(1-21)Online publication date: 8-Jun-2021
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Silberstein NSomekh OKoren YAharon MPorat DShahar AWu TCaverlee JHu XLalmas MWang W(2020)Ad Close Mitigation for Improved User Experience in Native AdvertisementsProceedings of the 13th International Conference on Web Search and Data Mining10.1145/3336191.3371798(546-554)Online publication date: 20-Jan-2020
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