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Mastering Java Machine Learning

You're reading from   Mastering Java Machine Learning A Java developer's guide to implementing machine learning and big data architectures

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Product type Paperback
Published in Jul 2017
Publisher Packt
ISBN-13 9781785880513
Length 556 pages
Edition 1st Edition
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Authors (2):
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Uday Kamath Uday Kamath
Author Profile Icon Uday Kamath
Uday Kamath
Krishna Choppella Krishna Choppella
Author Profile Icon Krishna Choppella
Krishna Choppella
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Table of Contents (13) Chapters Close

Preface 1. Machine Learning Review FREE CHAPTER 2. Practical Approach to Real-World Supervised Learning 3. Unsupervised Machine Learning Techniques 4. Semi-Supervised and Active Learning 5. Real-Time Stream Machine Learning 6. Probabilistic Graph Modeling 7. Deep Learning 8. Text Mining and Natural Language Processing 9. Big Data Machine Learning – The Final Frontier A. Linear Algebra B. Probability Index

Limitations of neural networks

In this section, we will discuss in detail the issues faced by neural networks, which will become the stepping stone for building deep learning networks.

Vanishing gradients, local optimum, and slow training

One of the major issues with neural networks is the problem of "vanishing gradient" (References [8]). We will try to give a simple explanation of the issue rather than exploring the mathematical derivations in depth. We will choose the sigmoid activation function and a two-layer neural network, as shown in the following figure, to demonstrate the issue:

Vanishing gradients, local optimum, and slow training

Figure 5: Vanishing Gradient issue.

As we saw in the activation function description, the sigmoid function squashes the output between the range 0 and 1. The derivative of the sigmoid function g'(a) = g(a)(1 – g(a)) has a range between 0 and 0.25. The goal of learning is to minimize the output loss, that is, Vanishing gradients, local optimum, and slow training. In general, the output error does not go to 0, so maximum iterations; a user...

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