Litcius/Paper detail

Distribution-free, Risk-controlling Prediction Sets

Stephen Bates, Anastasios N. Angelopoulos, Lihua Lei, Jitendra Malik, Michael I. Jordan

2021Journal of the ACM26 citationsDOIOpen Access PDF

Abstract

While improving prediction accuracy has been the focus of machine learning in recent years, this alone does not suffice for reliable decision-making. Deploying learning systems in consequential settings also requires calibrating and communicating the uncertainty of predictions. To convey instance-wise uncertainty for prediction tasks, we show how to generate set-valued predictions from a black-box predictor that controls the expected loss on future test points at a user-specified level. Our approach provides explicit finite-sample guarantees for any dataset by using a holdout set to calibrate the size of the prediction sets. This framework enables simple, distribution-free, rigorous error control for many tasks, and we demonstrate it in five large-scale machine learning problems: (1) classification problems where some mistakes are more costly than others; (2) multi-label classification, where each observation has multiple associated labels; (3) classification problems where the labels have a hierarchical structure; (4) image segmentation, where we wish to predict a set of pixels containing an object of interest; and (5) protein structure prediction. Last, we discuss extensions to uncertainty quantification for ranking, metric learning, and distributionally robust learning.

Topics & Concepts

Computer scienceMachine learningMetric (unit)Ranking (information retrieval)Artificial intelligenceBlack boxSet (abstract data type)Focus (optics)SegmentationSimple (philosophy)Data miningControl (management)Programming languagePhilosophyOpticsPhysicsOperations managementEconomicsEpistemologyMachine Learning and Data ClassificationMachine Learning and AlgorithmsAdversarial Robustness in Machine Learning