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July 15 – 20 , 2018, Dagstuhl Seminar 18291

Extreme Classification

Organizers

Samy Bengio (Google Inc. – Mountain View, US)
Krzysztof Dembczynski (Poznan University of Technology, PL)
Thorsten Joachims (Cornell University – Ithaca, US)
Marius Kloft (TU Kaiserslautern, DE)
Manik Varma (Microsoft Research India – Bangalore, IN)

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Documents

Dagstuhl Report, Volume 8, Issue 7 Dagstuhl Report
Aims & Scope
List of Participants
Shared Documents

Summary

The topic of this seminar is in the general context of machine learning [10] which concerns the study and development of algorithms that learn from empirical data how to make accurate predictions about yet unseen data without being explicitly programmed. Multi-class and multi-label learning are classical problems in machine learning. The outputs here stem from a finite set of categories (classes), and the aim is to classify each input into one (multi-class) or multiple (multi-label) out of several possible target classes. Classical applications of multi-class and multi-label learning include handwritten optical character recognition [8], part-of-speech tagging [11], and text categorization [7]. However, with the advent of the big data era, learning problems can involve even millions of classes. As examples let us consider the following problems:

  • Person recognition in Facebook images (there are billions of Facebook users; given an image, we might want to predict the subset of users present in the image for such applications like security, surveillance, social network analysis, etc.).
  • Predicting Wikipedia tags for new Wikipedia articles or webpages (Wikipedia has almost 2 million tags now).
  • Recommending Amazon items where each of the 100 million items on Amazon is a separate label.
  • Search on Google/Bing where each of the 100 million queries is a separate label.
  • Language modelling – predicting the next word in a sentence from the millions of words available.

The problems of this type are often referred to as extreme classification. They have posed new computational and statistical challenges and opened a new line of research within machine learning.

The main goal of extreme classification is to design learning and prediction algorithms, characterized by strong statistical guarantees, that exhibit sublinear time and space complexity in the number of classes. Unfortunately, the theoretical results obtained so far are still not satisfactory and very limited. Moreover, the problems at this scale often suffer from unreliable learning information, e.g., there is no chance to identify all positive labels and assign them precisely to training examples. The majority of labels is used very rarely, which leads to the problem of the long-tail distribution. In practical applications, learning algorithms run in rapidly changing environments. Hence, during testing/prediction phase new labels might appear that have not been present in the training set [4, 2]. This is the so-called zero-shot learning problem. Furthermore, typical performance measures used to assess the prediction quality of learning algorithms, such as 0/1 or Hamming loss, do not fit well to the nature of extreme classification problems. Therefore, other measures are often used such as precision@k [9] or the F-measure [6]. However, none of the above is appropriate to measure predictive performance in the long-tail problems or in the zero-shot setting. Hence, the goal is to design measures, which promote a high coverage of sparse labels [5].

The seminar aimed at bringing together researchers interested in extreme classification to encourage discussion on the above mentioned problems, identify the most important ones and promising research directions, foster collaboration and improve upon the state-of-the-art algorithms. The meeting in this regard was very successful as participants from both academia and industry as well as researchers from both core machine learning and applied areas such as recommender systems, computer vision, computational advertising, information retrieval and natural language processing, were given the opportunity to see similar problems from different angles.

The seminar consisted of invited talks, working groups, presentation of their results, and many informal discussions. The talks concerned among others such topics as: common applications of extreme classification, potential applications in bioinformatics and biotechnology, neural networks for extreme classification, learning theory for problems with a large number of labels, approaches for dealing with tail labels, learning and prediction algorithms, extreme classification challenges in natural language processing, multi-task learning with large number of tasks, pitfalls of multi-class classification, recommendation systems and their connection to extreme classification, counterfactual learning and zero-shot learning. The short abstracts of these talks can be found below in this report. The four working groups focused on the following problems: loss functions and types of predictions in multi-label classification, deep networks for extreme classification, zero-shot learning and long tail labels, and generalization bounds and log-time-and-space algorithms. Short summaries of the results obtained by the working groups can also be found below.

During the seminar, we also discussed different definitions of extreme classification. The basic one determines extreme classification as a multi-class or multi-label problem with a very large number of labels. The labels are rather typical identifiers without any explicit meaning. However, there usually exists some additional information about similarities between the labels (or this information can be extracted or learned from data). From this point of view, we can treat extreme classification as a learning problem with a weak structure over the labels. This is in difference to structured output prediction [1], where we assume much stronger knowledge about the structure. The most general definition, however, says that extreme classification concerns all problems with an extreme number of choices. The talks, working groups, and discussions have helped to gain a better understanding of existing algorithms, theoretical challenges, and practical problems not yet solved. We believe that the seminar has initiated many new collaborations and strengthen the existing ones that will soon deliver new results for the extreme classification problems.

References

  1. Bakir GH, Hofmann T, Schölkopf B, Smola AJ, Taskar B, Vishwanathan SVN (eds) Predicting Structured Data. Neural Information Processing, The MIT Press, 2007
  2. Andrea Frome, Gregory S. Corrado, Jonathon Shlens, Samy Bengio, Jeffrey Dean, Marc’Aurelio Ranzato, and Tomas Mikolov. Devise: A deep visual-semantic embedding model. In Advances in Neural Information Processing Systems, pages 2121–2129, 2013.
  3. Yann Guermeur. lp-norm Sauer-Shelah lemma for margin multi-category classifiers. arXiv preprint arXiv:1609.07953, 2016.
  4. Bharath Hariharan, S. V. N. Vishwanathan, and Manik Varma. Efficient max-margin multilabel classification with applications to zero-shot learning. Machine Learning, 88(1-2):127–155, 2012.
  5. Himanshu Jain, Yashoteja Prabhu, and Manik Varma. Extreme multi-label loss functions for recommendation, tagging, ranking & other missing label applications. In Proceedings of the 22nd ACM SIGKDD International Conference on Knowledge Discovery and Data Mining, KDD ’16, pages 935–944, New York, NY, USA, 2016. ACM.
  6. K. Jasinska, K. Dembczynski, R. Busa-Fekete, K. Pfannschmidt, T. Klerx, and E. Hüllermeier. Extreme F-measure maximization using sparse probability estimates. In Proceedings of the 33rd International Conference on International Conference on Machine Learning – Volume 48, pages 1435–1444, 2016.
  7. Thorsten Joachims. Text categorization with support vector machines: Learning with many relevant features. Springer, 1998.
  8. Nei Kato, Masato Suzuki, Shin Ichiro Omachi, Hirotomo Aso, and Yoshiaki Nemoto. A handwritten character recognition system using directional element feature and asymmetric mahalanobis distance. IEEE Transactions on Pattern Analysis and Machine Intelligence, 21(3):258–262, 1999.
  9. Yashoteja Prabhu and Manik Varma. Fastxml: A fast, accurate and stable tree-classifier for extreme multi-label learning. In Proceedings of the 20th ACM SIGKDD international conference on Knowledge discovery and data mining, pages 263–272. ACM, 2014.
  10. Vladimir Vapnik. Statistical learning theory, volume 1. Wiley New York, 1998.
  11. Atro Voutilainen. Part-of-speech tagging. The Oxford handbook of computational linguistics, pages 219–232, 2003.
License
  Creative Commons BY 3.0 Unported license
  Samy Bengio, Krzysztof Dembczynski, Thorsten Joachims, Marius Kloft, and Manik Varma

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