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Meta-Learning with Warped Gradient Descent

Machine Learning 2020-02-19 v2 Neural and Evolutionary Computing Machine Learning

Abstract

Learning an efficient update rule from data that promotes rapid learning of new tasks from the same distribution remains an open problem in meta-learning. Typically, previous works have approached this issue either by attempting to train a neural network that directly produces updates or by attempting to learn better initialisations or scaling factors for a gradient-based update rule. Both of these approaches pose challenges. On one hand, directly producing an update forgoes a useful inductive bias and can easily lead to non-converging behaviour. On the other hand, approaches that try to control a gradient-based update rule typically resort to computing gradients through the learning process to obtain their meta-gradients, leading to methods that can not scale beyond few-shot task adaptation. In this work, we propose Warped Gradient Descent (WarpGrad), a method that intersects these approaches to mitigate their limitations. WarpGrad meta-learns an efficiently parameterised preconditioning matrix that facilitates gradient descent across the task distribution. Preconditioning arises by interleaving non-linear layers, referred to as warp-layers, between the layers of a task-learner. Warp-layers are meta-learned without backpropagating through the task training process in a manner similar to methods that learn to directly produce updates. WarpGrad is computationally efficient, easy to implement, and can scale to arbitrarily large meta-learning problems. We provide a geometrical interpretation of the approach and evaluate its effectiveness in a variety of settings, including few-shot, standard supervised, continual and reinforcement learning.

Keywords

Cite

@article{arxiv.1909.00025,
  title  = {Meta-Learning with Warped Gradient Descent},
  author = {Sebastian Flennerhag and Andrei A. Rusu and Razvan Pascanu and Francesco Visin and Hujun Yin and Raia Hadsell},
  journal= {arXiv preprint arXiv:1909.00025},
  year   = {2020}
}

Comments

28 pages, 13 figures, 3 tables. Published as a conference paper at ICLR 2020

R2 v1 2026-06-23T11:01:39.717Z