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On the Importance of Strong Baselines in Bayesian Deep Learning

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arxiv 1811.09385 v2 pith:KAY4OX6S submitted 2018-11-23 cs.LG stat.ML

On the Importance of Strong Baselines in Bayesian Deep Learning

classification cs.LG stat.ML
keywords experimentallearningbaselinebayesiandeepexperimentbaselinesbeen
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Like all sub-fields of machine learning Bayesian Deep Learning is driven by empirical validation of its theoretical proposals. Given the many aspects of an experiment it is always possible that minor or even major experimental flaws can slip by both authors and reviewers. One of the most popular experiments used to evaluate approximate inference techniques is the regression experiment on UCI datasets. However, in this experiment, models which have been trained to convergence have often been compared with baselines trained only for a fixed number of iterations. We find that a well-established baseline, Monte Carlo dropout, when evaluated under the same experimental settings shows significant improvements. In fact, the baseline outperforms or performs competitively with methods that claimed to be superior to the very same baseline method when they were introduced. Hence, by exposing this flaw in experimental procedure, we highlight the importance of using identical experimental setups to evaluate, compare, and benchmark methods in Bayesian Deep Learning.

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