Spectral pruning of fully connected layers

Lorenzo Giambagli; Lorenzo Buffoni; Lorenzo Chicchi; Enrico Civitelli; Duccio Fanelli

doi:10.1038/s41598-022-14805-7

Spectral pruning of fully connected layers

Lorenzo Giambagli, Lorenzo Buffoni, Lorenzo Chicchi, Enrico Civitelli, Duccio Fanelli

Namur Institute for Complex Systems

Research output: Contribution to journal › Article › peer-review

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Abstract

Training of neural networks can be reformulated in spectral space, by allowing eigenvalues and eigenvectors of the network to act as target of the optimization instead of the individual weights. Working in this setting, we show that the eigenvalues can be used to rank the nodes’ importance within the ensemble. Indeed, we will prove that sorting the nodes based on their associated eigenvalues, enables effective pre- and post-processing pruning strategies to yield massively compacted networks (in terms of the number of composing neurons) with virtually unchanged performance. The proposed methods are tested for different architectures, with just a single or multiple hidden layers, and against distinct classification tasks of general interest.

Original language	English
Article number	11201
Journal	Scientific Reports
Volume	12
Issue number	1
DOIs	https://doi.org/10.1038/s41598-022-14805-7
Publication status	Published - 1 Jul 2022

Keywords

Pruning
Machine Learning
Feedforward Neural Networks
Dense Layer

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10.1038/s41598-022-14805-7

Spectral Pruning Fully connected layersFinal published version, 1.65 MB

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title = "Spectral pruning of fully connected layers",

abstract = "Training of neural networks can be reformulated in spectral space, by allowing eigenvalues and eigenvectors of the network to act as target of the optimization instead of the individual weights. Working in this setting, we show that the eigenvalues can be used to rank the nodes{\textquoteright} importance within the ensemble. Indeed, we will prove that sorting the nodes based on their associated eigenvalues, enables effective pre- and post-processing pruning strategies to yield massively compacted networks (in terms of the number of composing neurons) with virtually unchanged performance. The proposed methods are tested for different architectures, with just a single or multiple hidden layers, and against distinct classification tasks of general interest.",

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author = "Lorenzo Giambagli and Lorenzo Buffoni and Lorenzo Chicchi and Enrico Civitelli and Duccio Fanelli",

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AU - Giambagli, Lorenzo

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AU - Chicchi, Lorenzo

AU - Civitelli, Enrico

AU - Fanelli, Duccio

PY - 2022/7/1

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N2 - Training of neural networks can be reformulated in spectral space, by allowing eigenvalues and eigenvectors of the network to act as target of the optimization instead of the individual weights. Working in this setting, we show that the eigenvalues can be used to rank the nodes’ importance within the ensemble. Indeed, we will prove that sorting the nodes based on their associated eigenvalues, enables effective pre- and post-processing pruning strategies to yield massively compacted networks (in terms of the number of composing neurons) with virtually unchanged performance. The proposed methods are tested for different architectures, with just a single or multiple hidden layers, and against distinct classification tasks of general interest.

AB - Training of neural networks can be reformulated in spectral space, by allowing eigenvalues and eigenvectors of the network to act as target of the optimization instead of the individual weights. Working in this setting, we show that the eigenvalues can be used to rank the nodes’ importance within the ensemble. Indeed, we will prove that sorting the nodes based on their associated eigenvalues, enables effective pre- and post-processing pruning strategies to yield massively compacted networks (in terms of the number of composing neurons) with virtually unchanged performance. The proposed methods are tested for different architectures, with just a single or multiple hidden layers, and against distinct classification tasks of general interest.

KW - Pruning

KW - Machine Learning

KW - Feedforward Neural Networks

KW - Dense Layer

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VL - 12

JO - Scientific Reports

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ER -

Spectral pruning of fully connected layers

Abstract

Keywords

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Spectral Tools for Neural Networks

A Journey Through Reciprocal Space: from Deep Spectral Learning to Topological Signals

Cite this

Spectral pruning of fully connected layers

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Research output

Spectral Tools for Neural Networks

Student theses

A Journey Through Reciprocal Space: from Deep Spectral Learning to Topological Signals

Cite this