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Greedy Layer-Wise Training of Deep Networks

2007· book-chapter· en· 4,704 citations· W2110798204 on OpenAlex· 10.7551/mitpress/7503.003.0024

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Abstract

Complexity theory of circuits strongly suggests that deep architectures can be much more efficient (sometimes exponentially) than shallow architectures, in terms of computational elements required to represent some functions. Deep multi-layer neural networks have many levels of non-linearities allowing them to compactly represent highly non-linear and highly-varying functions. However, until recently it was not clear how to train such deep networks, since gradient-based optimization starting from random initialization appears to often get stuck in poor solutions. Hinton et al. recently introduced a greedy layer-wise unsupervised learning algorithm for Deep Belief Networks (DBN), a generative model with many layers of hidden causal variables. In the context of the above optimization problem, we study this algorithm empirically and explore variants to better understand its success and extend it to cases where the inputs are continuous or where the structure of the input distribution is not revealing enough about the variable to be predicted in a supervised task. Our experiments also confirm the hypothesis that the greedy layer-wise unsupervised training strategy mostly helps the optimization, by initializing weights in a region near a good local minimum, giving rise to internal distributed representations that are high-level abstractions of the input, bringing better generalization.

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The record

Venue
The MIT Press eBooks
Topic
Generative Adversarial Networks and Image Synthesis
Field
Computer Science
Canadian institutions
Université de Montréal
Funders
Keywords
Training (meteorology)Layer (electronics)Computer scienceArtificial intelligenceGeographyMaterials scienceComposite materialMeteorology
Has abstract in OpenAlex
yes