- We will send in 10–14 business days.
/https://libri-media.knygos-static.lt/e9ca4679-0c04-48c8-b5fa-0f6d437c006c/13)
- Author: Anthony Caterini, Dong Eui Chang
- Publisher: Springer-Verlag GmbH
- Year: 2018
- Pages: 100
- ISBN-10: 3319753037
- ISBN-13: 9783319753034
- Format: 15.9 x 24.1 x 1 cm, hardcover
- Language: English
- SAVE -10% with code: EXTRA
Deep Neural Networks in a Mathematical Framework (e-book) (used book) | bookbook.eu
Reviews
Description
This SpringerBrief describes how to build a rigorous end-to-end mathematical framework for deep neural networks. The authors provide tools to represent and describe neural networks, casting previous results in the field in a more natural light. In particular, the authors derive gradient descent algorithms in a unified way for several neural network structures, including multilayer perceptrons, convolutional neural networks, deep autoencoders and recurrent neural networks. Furthermore, the authors developed framework is both more concise and mathematically intuitive than previous representations of neural networks.
This SpringerBrief is one step towards unlocking the black box of Deep Learning. The authors believe that this framework will help catalyze further discoveries regarding the mathematical properties of neural networks.This SpringerBrief is accessible not only to researchers, professionals and students working and studying in the field of deep learning, but also to those outside of the neutral network community.
EXTRA 10 % discount with code: EXTRA
The promotion ends in 20d.15:32:39
The discount code is valid when purchasing from 10 €. Discounts do not stack.
- Author: Anthony Caterini, Dong Eui Chang
- Publisher: Springer-Verlag GmbH
- Year: 2018
- Pages: 100
- ISBN-10: 3319753037
- ISBN-13: 9783319753034
- Format: 15.9 x 24.1 x 1 cm, hardcover
- Language: English English
This SpringerBrief describes how to build a rigorous end-to-end mathematical framework for deep neural networks. The authors provide tools to represent and describe neural networks, casting previous results in the field in a more natural light. In particular, the authors derive gradient descent algorithms in a unified way for several neural network structures, including multilayer perceptrons, convolutional neural networks, deep autoencoders and recurrent neural networks. Furthermore, the authors developed framework is both more concise and mathematically intuitive than previous representations of neural networks.
This SpringerBrief is one step towards unlocking the black box of Deep Learning. The authors believe that this framework will help catalyze further discoveries regarding the mathematical properties of neural networks.This SpringerBrief is accessible not only to researchers, professionals and students working and studying in the field of deep learning, but also to those outside of the neutral network community.
Reviews