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Learning the Stein Discrepancy for Training and Evaluating Energy-Based Models without Sampling

Will Grathwohl, Kuan-Chieh Wang, Jörn-Henrik Jacobsen, David Duvenaud, Richard S. Zemel

2020International Conference on Machine Learning20 citations

Abstract

We present a new method for evaluating and training unnormalized density models. Our approach only requires access to the gradient of the unnormalized model's log-density. We estimate the Stein discrepancy between the data density $p(x)$ and the model density $q(x)$ defined by a vector function of the data. We parameterize this function with a neural network and fit its parameters to maximize the discrepancy. This yields a novel goodness-of-fit test which outperforms existing methods on high dimensional data. Furthermore, optimizing $q(x)$ to minimize this discrepancy produces a novel method for training unnormalized models which scales more gracefully than existing methods. The ability to both learn and compare models is a unique feature of the proposed method.

Topics & Concepts

Computer scienceArtificial neural networkSampling (signal processing)Function (biology)Artificial intelligenceTraining setGoodness of fitEnergy (signal processing)Feature (linguistics)Data modelingMachine learningAlgorithmMathematicsStatisticsComputer visionPhilosophyEvolutionary biologyDatabaseLinguisticsFilter (signal processing)BiologyGenerative Adversarial Networks and Image SynthesisAdversarial Robustness in Machine LearningStochastic Gradient Optimization Techniques
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