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Neural Network Programming with TensorFlow

You're reading from   Neural Network Programming with TensorFlow Unleash the power of TensorFlow to train efficient neural networks

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Product type Paperback
Published in Nov 2017
Publisher Packt
ISBN-13 9781788390392
Length 274 pages
Edition 1st Edition
Languages
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Authors (2):
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Manpreet Singh Ghotra Manpreet Singh Ghotra
Author Profile Icon Manpreet Singh Ghotra
Manpreet Singh Ghotra
Rajdeep Dua Rajdeep Dua
Author Profile Icon Rajdeep Dua
Rajdeep Dua
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Toc

Table of Contents (11) Chapters Close

Preface 1. Maths for Neural Networks FREE CHAPTER 2. Deep Feedforward Networks 3. Optimization for Neural Networks 4. Convolutional Neural Networks 5. Recurrent Neural Networks 6. Generative Models 7. Deep Belief Networking 8. Autoencoders 9. Research in Neural Networks 10. Getting started with TensorFlow

Autoencoder algorithms


In the following notation, x is the input, y is the encoded data, z is the decoded data, σ is a nonlinear activation function (sigmoid or hyperbolic tangent, usually), and f(x;θ) means a function of x parameterized by θ.

The model can be summarized in the following way:

The input data is mapped to the hidden layer (encoding). The mapping is usually an affine (allowing for or preserving parallel relationships.) transformation followed by a non-linearity:

y = f(x;θ) = σ(Wx+b)y = f(x;θ) =σ(Wx+b)

The hidden layer is mapped to the output layer, which is also called decoding. The mapping is an affine transformation (affine transformation is a linear mapping method that preserves points, straight lines, and planes) optionally followed by a non linearity. The following equation explains this:

z = g(y;θ′) = g(f(x;θ);θ′) = σ(W′y+b′)

In order to reduce the size of the model, tied weights can be used, which means that the decoder weights matrix is constrained and can be the transpose...

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