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Optimizing Sequential Experimental Design with Deep Reinforcement Learning

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arxiv 2202.00821 v3 pith:QSSDBHCT submitted 2022-02-02 cs.LG stat.ML

Optimizing Sequential Experimental Design with Deep Reinforcement Learning

classification cs.LG stat.ML
keywords designapproachesbayesiancomputationallycontinuousdeepdeploymentexperiments
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Bayesian approaches developed to solve the optimal design of sequential experiments are mathematically elegant but computationally challenging. Recently, techniques using amortization have been proposed to make these Bayesian approaches practical, by training a parameterized policy that proposes designs efficiently at deployment time. However, these methods may not sufficiently explore the design space, require access to a differentiable probabilistic model and can only optimize over continuous design spaces. Here, we address these limitations by showing that the problem of optimizing policies can be reduced to solving a Markov decision process (MDP). We solve the equivalent MDP with modern deep reinforcement learning techniques. Our experiments show that our approach is also computationally efficient at deployment time and exhibits state-of-the-art performance on both continuous and discrete design spaces, even when the probabilistic model is a black box.

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