2 layer neural networks as Wasserstein gradient flows: Difference between revisions
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<ref name="Figalli" /> | <ref name="Figalli" /> | ||
[https://en.wikipedia.org/wiki/Artificial_neural_network#:~:text=Artificial%20neural%20networks%20(ANNs)%2C,neurons%20in%20a%20biological%20brain. | [https://en.wikipedia.org/wiki/Artificial_neural_network#:~:text=Artificial%20neural%20networks%20(ANNs)%2C,neurons%20in%20a%20biological%20brain. Artificial neural networks] (ANNs) consist of layers of artificial "neurons" which take in information from the previous layer and output information to the next layer. Gradient descent is a common method for updating the weights of each neuron based on training data. While in practice every layer of a neural network has only finitely many neurons, it is beneficial to consider a neural network layer with infinitely many neurons, for the sake of developing a theory that explains how ANNs work. In particular, from this viewpoint the process of updating the neuron weights for a shallow neural network can be described by a Wasserstein gradient flow. | ||
==Motivation== | ==Motivation== | ||
Revision as of 03:16, 10 February 2022
Artificial neural networks (ANNs) consist of layers of artificial "neurons" which take in information from the previous layer and output information to the next layer. Gradient descent is a common method for updating the weights of each neuron based on training data. While in practice every layer of a neural network has only finitely many neurons, it is beneficial to consider a neural network layer with infinitely many neurons, for the sake of developing a theory that explains how ANNs work. In particular, from this viewpoint the process of updating the neuron weights for a shallow neural network can be described by a Wasserstein gradient flow.