Your search keyword '"Ben-Porat, Omer"' showing total 5 results

1. Modeling Attrition in Recommender Systems with Departing Bandits

Author

Ben-Porat, Omer, Cohen, Lee, Leqi, Liu, Lipton, Zachary C., and Mansour, Yishay

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Statistics - Machine Learning, Machine Learning (stat.ML), General Medicine, Information Retrieval (cs.IR), Computer Science - Information Retrieval, Machine Learning (cs.LG)

Abstract

Traditionally, when recommender systems are formalized as multi-armed bandits, the policy of the recommender system influences the rewards accrued, but not the length of interaction. However, in real-world systems, dissatisfied users may depart (and never come back). In this work, we propose a novel multi-armed bandit setup that captures such policy-dependent horizons. Our setup consists of a finite set of user types, and multiple arms with Bernoulli payoffs. Each (user type, arm) tuple corresponds to an (unknown) reward probability. Each user's type is initially unknown and can only be inferred through their response to recommendations. Moreover, if a user is dissatisfied with their recommendation, they might depart the system. We first address the case where all users share the same type, demonstrating that a recent UCB-based algorithm is optimal. We then move forward to the more challenging case, where users are divided among two types. While naive approaches cannot handle this setting, we provide an efficient learning algorithm that achieves $\tilde{O}(\sqrt{T})$ regret, where $T$ is the number of users., Comment: Accepted at AAAI 2022

Published

2022

2. Learning under Invariable Bayesian Safety

Author

Bahar, Gal, Ben-Porat, Omer, Leyton-Brown, Kevin, and Tennenholtz, Moshe

Subjects

FOS: Computer and information sciences, Computer Science - Computers and Society, Computer Science - Machine Learning, Artificial Intelligence (cs.AI), Computer Science - Computer Science and Game Theory, Computer Science - Artificial Intelligence, Computers and Society (cs.CY), Computer Science and Game Theory (cs.GT), Machine Learning (cs.LG)

Abstract

A recent body of work addresses safety constraints in explore-and-exploit systems. Such constraints arise where, for example, exploration is carried out by individuals whose welfare should be balanced with overall welfare. In this paper, we adopt a model inspired by recent work on a bandit-like setting for recommendations. We contribute to this line of literature by introducing a safety constraint that should be respected in every round and determines that the expected value in each round is above a given threshold. Due to our modeling, the safe explore-and-exploit policy deserves careful planning, or otherwise, it will lead to sub-optimal welfare. We devise an asymptotically optimal algorithm for the setting and analyze its instance-dependent convergence rate.

Published

2020

3. Optimizing Long-term Social Welfare in Recommender Systems: A Constrained Matching Approach

Author

Mladenov, Martin, Creager, Elliot, Ben-Porat, Omer, Swersky, Kevin, Zemel, Richard, and Boutilier, Craig

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Artificial Intelligence (cs.AI), Computer Science - Artificial Intelligence, Statistics - Machine Learning, Machine Learning (stat.ML), Information Retrieval (cs.IR), Computer Science - Information Retrieval, Machine Learning (cs.LG)

Abstract

Most recommender systems (RS) research assumes that a user's utility can be maximized independently of the utility of the other agents (e.g., other users, content providers). In realistic settings, this is often not true---the dynamics of an RS ecosystem couple the long-term utility of all agents. In this work, we explore settings in which content providers cannot remain viable unless they receive a certain level of user engagement. We formulate the recommendation problem in this setting as one of equilibrium selection in the induced dynamical system, and show that it can be solved as an optimal constrained matching problem. Our model ensures the system reaches an equilibrium with maximal social welfare supported by a sufficiently diverse set of viable providers. We demonstrate that even in a simple, stylized dynamical RS model, the standard myopic approach to recommendation---always matching a user to the best provider---performs poorly. We develop several scalable techniques to solve the matching problem, and also draw connections to various notions of user regret and fairness, arguing that these outcomes are fairer in a utilitarian sense.

Published

2020

4. Fiduciary Bandits

Author

Bahar, Gal, Ben-Porat, Omer, Leyton-Brown, Kevin, and Tennenholtz, Moshe

Subjects

FOS: Computer and information sciences, Computer Science - Machine Learning, Computer Science - Computer Science and Game Theory, Information Retrieval (cs.IR), Computer Science - Information Retrieval, Computer Science and Game Theory (cs.GT), Machine Learning (cs.LG)

Abstract

Recommendation systems often face exploration-exploitation tradeoffs: the system can only learn about the desirability of new options by recommending them to some user. Such systems can thus be modeled as multi-armed bandit settings; however, users are self-interested and cannot be made to follow recommendations. We ask whether exploration can nevertheless be performed in a way that scrupulously respects agents' interests---i.e., by a system that acts as a fiduciary. More formally, we introduce a model in which a recommendation system faces an exploration-exploitation tradeoff under the constraint that it can never recommend any action that it knows yields lower reward in expectation than an agent would achieve if it acted alone. Our main contribution is a positive result: an asymptotically optimal, incentive compatible, and ex-ante individually rational recommendation algorithm., Comment: Published in The Thirty-seventh International Conference on Machine Learning (ICML 2020)

Published

2019

5. Competing Prediction Algorithms

Author

Ben-Porat, Omer and Tennenholtz, Moshe

Subjects

FOS: Computer and information sciences, Computer Science::Computer Science and Game Theory, Computer Science - Computer Science and Game Theory, Computer Science and Game Theory (cs.GT)

Abstract

Prediction is a well-studied machine learning task, and prediction algorithms are core ingredients in online products and services. Despite their centrality in the competition between online companies who offer prediction-based products, the strategic use of prediction algorithms remains unexplored. The goal of this paper is to examine strategic use of prediction algorithms. We introduce a novel game-theoretic setting that is based on the PAC learning framework, where each player (aka a prediction algorithm at competition) seeks to maximize the sum of points for which it produces an accurate prediction and the others do not. We show that algorithms aiming at generalization may wittingly miss-predict some points to perform better than others on expectation. We analyze the empirical game, i.e. the game induced on a given sample, prove that it always possesses a pure Nash equilibrium, and show that every better-response learning process converges. Moreover, our learning-theoretic analysis suggests that players can, with high probability, learn an approximate pure Nash equilibrium for the whole population using a small number of samples., Comment: An updated and significantly improved version of this paper was published in Economics and Computation 2019 under the name "Regression Equilibrium", and is publicly available here: arXiv:1905.02576

Published

2018