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Hands-On Artificial Intelligence for IoT

You're reading from   Hands-On Artificial Intelligence for IoT Expert machine learning and deep learning techniques for developing smarter IoT systems

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Product type Paperback
Published in Jan 2019
Publisher Packt
ISBN-13 9781788836067
Length 390 pages
Edition 2nd Edition
Languages
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Author (1):
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Dr. Amita Kapoor Dr. Amita Kapoor
Author Profile Icon Dr. Amita Kapoor
Dr. Amita Kapoor
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Table of Contents (14) Chapters Close

Preface 1. Principles and Foundations of IoT and AI 2. Data Access and Distributed Processing for IoT FREE CHAPTER 3. Machine Learning for IoT 4. Deep Learning for IoT 5. Genetic Algorithms for IoT 6. Reinforcement Learning for IoT 7. Generative Models for IoT 8. Distributed AI for IoT 9. Personal and Home IoT 10. AI for the Industrial IoT 11. AI for Smart Cities IoT 12. Combining It All Together 13. Other Books You May Enjoy

Generating images using VAEs


From Chapter 4, Deep Learning for IOT, you should be familiar with autoencoders and their functions. VAEs are a type of autoencoder; here, we retain the (trained) Decoder part, which can be used by feeding random latent features z to generate data similar to the training data. Now, if you remember, in autoencoders, the Encoder results in the generation of low-dimensional features, z:

The architecture of autoencoders

The VAEs are concerned with finding the likelihood function p(x) from the latent features z

This is an intractable density function, and it isn't possible to directly optimize it; instead, we obtain a lower bound by using a simple Gaussian prior p(z) and making both Encoder and Decoder networks probabilistic:

 Architecture of a VAE

This allows us to define a tractable lower bound on the log likelihood, given by the following:

In the preceding, θ represents the decoder network parameters and φ the encoder network parameters. The network is trained by maximizing...

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