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Learned Optimizers that Scale and Generalize

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arxiv 1703.04813 v4 pith:F74KQGQU submitted 2017-03-14 cs.LG cs.NEstat.ML

Learned Optimizers that Scale and Generalize

classification cs.LG cs.NEstat.ML
keywords tasksmeta-trainingoptimizationproblemsscalegeneralizegeneralizeslearned
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Learning to learn has emerged as an important direction for achieving artificial intelligence. Two of the primary barriers to its adoption are an inability to scale to larger problems and a limited ability to generalize to new tasks. We introduce a learned gradient descent optimizer that generalizes well to new tasks, and which has significantly reduced memory and computation overhead. We achieve this by introducing a novel hierarchical RNN architecture, with minimal per-parameter overhead, augmented with additional architectural features that mirror the known structure of optimization tasks. We also develop a meta-training ensemble of small, diverse optimization tasks capturing common properties of loss landscapes. The optimizer learns to outperform RMSProp/ADAM on problems in this corpus. More importantly, it performs comparably or better when applied to small convolutional neural networks, despite seeing no neural networks in its meta-training set. Finally, it generalizes to train Inception V3 and ResNet V2 architectures on the ImageNet dataset for thousands of steps, optimization problems that are of a vastly different scale than those it was trained on. We release an open source implementation of the meta-training algorithm.

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