Python Deep Learning

By : Vasilev, Daniel Slater, Spacagna, Roelants, Zocca

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Buy this Book

Python Deep Learning

4 (8)

By: Vasilev, Daniel Slater, Spacagna, Roelants, Zocca

Buy this Book

Overview of this book

With the surge in artificial intelligence in applications catering to both business and consumer needs, deep learning is more important than ever for meeting current and future market demands. With this book, you’ll explore deep learning, and learn how to put machine learning to use in your projects. This second edition of Python Deep Learning will get you up to speed with deep learning, deep neural networks, and how to train them with high-performance algorithms and popular Python frameworks. You’ll uncover different neural network architectures, such as convolutional networks, recurrent neural networks, long short-term memory (LSTM) networks, and capsule networks. You’ll also learn how to solve problems in the fields of computer vision, natural language processing (NLP), and speech recognition. You'll study generative model approaches such as variational autoencoders and Generative Adversarial Networks (GANs) to generate images. As you delve into newly evolved areas of reinforcement learning, you’ll gain an understanding of state-of-the-art algorithms that are the main components behind popular games Go, Atari, and Dota. By the end of the book, you will be well-versed with the theory of deep learning along with its real-world applications.

Preface

Who this book is for

What this book covers

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Free Chapter

Machine Learning - an Introduction

Introduction to machine learning

Different machine learning approaches

Neural networks

Summary

Neural Networks

The need for neural networks

An introduction to neural networks

Training neural networks

Summary

Deep Learning Fundamentals

Introduction to deep learning

Fundamental deep learning concepts

Deep learning algorithms

Applications of deep learning

The reasons for deep learning's popularity

Introducing popular open source libraries

Summary

Computer Vision with Convolutional Networks

Intuition and justification for CNN

Convolutional layers

Stride and padding in convolutional layers

Pooling layers

The structure of a convolutional network

Improving the performance of CNNs

A CNN example with Keras and CIFAR-10

Summary

Advanced Computer Vision

Transfer learning

Advanced network architectures

Capsule networks

Advanced computer vision tasks

Artistic style transfer

Summary

Generating Images with GANs and VAEs

Intuition and justification of generative models

Variational autoencoders

Generative Adversarial networks

Summary

Recurrent Neural Networks and Language Models

Recurrent neural networks

Language modeling

Sequence to sequence learning

Speech recognition

Summary

Reinforcement Learning Theory

RL paradigms

RL as a Markov decision process

Finding optimal policies with Dynamic Programming

Monte Carlo methods

Temporal difference methods

Value function approximations

Experience replay

Q-learning in action

Summary

Deep Reinforcement Learning for Games

Introduction to genetic algorithms playing games

Deep Q-learning

Policy gradient methods

Model-based methods

Summary

Deep Learning in Autonomous Vehicles

Brief history of AV research

AV introduction

Imitiation driving policy

Driving policy with ChauffeurNet

DL in the Cloud

Summary

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Introducing popular open source libraries

There are many open-source libraries that allow the creation of deep neural nets in Python, without having to explicitly write the code from scratch. In this book, we'll use three of the most popular: - TensorFlow, Keras, and PyTorch. They all share some common features, as follows:

The basic unit for data storage is the tensor. Consider the tensor as a generalization of a matrix to higher dimensions. Mathematically, the definition of a tensor is more complex, but in the context of deep learning libraries, they are multi-dimensional arrays of base values. A tensor is similar to a NumPy array and is made up of the following:
- A basic data type of tensor elements. These can vary between libraries, but typically include 16-, 32-, and 64-bit float and 8-, 16-, 32-, and 64-bit integers.
- An arbitrary number of axes (also known as the rank...