From Social to Individuals: A Parsimonious Path of Multi-Level Models for Crowdsourced Preference Aggregation

• Published in: IEEE transactions on pattern analysis and machine intelligence Vol. 41; no. 4; pp. 844 - 856
• Main Authors: Xu, Qianqian, Xiong, Jiechao, Cao, Xiaochun, Huang, Qingming, Yao, Yuan
• Format: Journal Article
• Language: English
• Published: United States IEEE 01.04.2019; The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
• Subjects: Adaptation models; Agglomeration; Algorithms; Computer simulation; Crowdsourcing; Data analysis; Data models; HodgeRank; Linearization; linearized bregman iterations; mixed-effects models; Motion pictures; Multiple criterion; personalized ranking; position bias; Predictive models; Preference aggregation; Preferences
• ISSN: 0162-8828; 1939-3539; 2160-9292
• DOI: 10.1109/TPAMI.2018.2817205

In crowdsourced preference aggregation, it is often assumed that all the annotators are subject to a common preference or social utility function which generates their comparison behaviors in experiments. However, in reality, annotators are subject to variations due to multi-criteria, abnormal, or a mixture of such behaviors. In this paper, we propose a parsimonious mixed-effects model, which takes into account both the fixed effect that the majority of annotators follows a common linear utility model, and the random effect that some annotators might deviate from the common significantly and exhibit strongly personalized preferences. The key algorithm in this paper establishes a dynamic path from the social utility to individual variations, with different levels of sparsity on personalization. The algorithm is based on the Linearized Bregman Iterations, which leads to easy parallel implementations to meet the need of large-scale data analysis. In this unified framework, three kinds of random utility models are presented, including the basic linear model with <inline-formula><tex-math notation="LaTeX">L_2</tex-math> <inline-graphic xlink:href="yao-ieq1-2817205.gif"/> </inline-formula> loss, Bradley-Terry model, and Thurstone-Mosteller model. The validity of these multi-level models are supported by experiments with both simulated and real-world datasets, which shows that the parsimonious multi-level models exhibit improvements in both interpretability and predictive precision compared with traditional HodgeRank.