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Hands-On Neuroevolution with Python

You're reading from   Hands-On Neuroevolution with Python Build high-performing artificial neural network architectures using neuroevolution-based algorithms

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Product type Paperback
Published in Dec 2019
Publisher Packt
ISBN-13 9781838824914
Length 368 pages
Edition 1st Edition
Languages
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Author (1):
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Iaroslav Omelianenko Iaroslav Omelianenko
Author Profile Icon Iaroslav Omelianenko
Iaroslav Omelianenko
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Table of Contents (18) Chapters Close

Preface 1. Section 1: Fundamentals of Evolutionary Computation Algorithms and Neuroevolution Methods FREE CHAPTER
2. Overview of Neuroevolution Methods 3. Python Libraries and Environment Setup 4. Section 2: Applying Neuroevolution Methods to Solve Classic Computer Science Problems
5. Using NEAT for XOR Solver Optimization 6. Pole-Balancing Experiments 7. Autonomous Maze Navigation 8. Novelty Search Optimization Method 9. Section 3: Advanced Neuroevolution Methods
10. Hypercube-Based NEAT for Visual Discrimination 11. ES-HyperNEAT and the Retina Problem 12. Co-Evolution and the SAFE Method 13. Deep Neuroevolution 14. Section 4: Discussion and Concluding Remarks
15. Best Practices, Tips, and Tricks 16. Concluding Remarks 17. Other Books You May Enjoy

Quadtree information extraction and ES-HyperNEAT basics

For the effective calculation of the information density within the connectivity patterns of the substrate, we need to use an appropriate data structure. We need to employ a data structure that allows an effective search through the two-dimensional substrate space at different levels of granularity. In computer science, there is a data structure that perfectly fits these requirements. This structure is the quadtree.

The quadtree is a data structure that allows us to organize an effective search through two-dimensional space by splitting any area of interest into four subareas. Each of these subareas consequently becomes a leaf of a tree, with the root node representing the initial region.

ES-HyperNEAT employs the quadtree data structure to iteratively look for the new connections and nodes in the substrate, starting from...

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