deep Generative Stochastic Networks Trainable by Backprop: Difference between revisions
Dylandrover (talk | contribs) No edit summary |
Dylandrover (talk | contribs) No edit summary |
||
| Line 12: | Line 12: | ||
GSN parameterixe transition operators of Markiv chain rather than P(X). Allows for training of unsupervised methods by gradient descent and ML no partition functions, just backprop | GSN parameterixe transition operators of Markiv chain rather than P(X). Allows for training of unsupervised methods by gradient descent and ML no partition functions, just backprop | ||
graphical models have too many computations (inference, sampling, learning) MCMC can be used for estimation if only a few terms dominate the weighted sum that is being calculated. | |||
= Generative Stochastic Network (GSN) = | = Generative Stochastic Network (GSN) = | ||
GSN relies on estimating the transition operator of a Markov chain. | |||
= Critique = | = Critique = | ||
Mentions SPN | |||
Revision as of 16:36, 18 November 2015
Introduction
The Deep Learning boom that has been seen in recent years was spurred initially by research in unsupervised learning techniques. However, most of the major successes over the last few years have mostly been based on supervised techniques.
Motivation
Unsupervised learning is attractive because the quantity of unlabelled data far exceeds that of labelled data
Avoiding intractable sums or maximization that is inherent in many unsupervised techniques
Generalize autoencoders
GSN parameterixe transition operators of Markiv chain rather than P(X). Allows for training of unsupervised methods by gradient descent and ML no partition functions, just backprop
graphical models have too many computations (inference, sampling, learning) MCMC can be used for estimation if only a few terms dominate the weighted sum that is being calculated.
Generative Stochastic Network (GSN)
GSN relies on estimating the transition operator of a Markov chain.
Critique
Mentions SPN