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Network Science with Python and NetworkX Quick Start Guide

By : Platt

5 (3)

Network Science with Python and NetworkX Quick Start Guide

5 (3)

By: Platt

Overview of this book

NetworkX is a leading free and open source package used for network science with the Python programming language. NetworkX can track properties of individuals and relationships, find communities, analyze resilience, detect key network locations, and perform a wide range of important tasks. With the recent release of version 2, NetworkX has been updated to be more powerful and easy to use. If you’re a data scientist, engineer, or computational social scientist, this book will guide you in using the Python programming language to gain insights into real-world networks. Starting with the fundamentals, you’ll be introduced to the core concepts of network science, along with examples that use real-world data and Python code. This book will introduce you to theoretical concepts such as scale-free and small-world networks, centrality measures, and agent-based modeling. You’ll also be able to look for scale-free networks in real data and visualize a network using circular, directed, and shell layouts. By the end of this book, you’ll be able to choose appropriate network representations, use NetworkX to build and characterize networks, and uncover insights while working with real-world systems.

Preface

Preface

Who this book is for

What this book covers

To get the most out of this book

Get in touch

Free Chapter

What is a Network?

What is a Network?

Network science

What is a network?

What is NetworkX?

Types of networks

Your first network in NetworkX

Summary

References

Working with Networks in NetworkX

Working with Networks in NetworkX

The Graph class – undirected networks

Adding attributes to nodes and edges

Adding edge weights

The DiGraph class – when direction matters

MultiGraph and MultiDiGraph – parallel edges

Summary

References

From Data to Networks

From Data to Networks

Modeling your data

Reading and writing network files

Creating a network with code

Summary

References

Affiliation Networks

Affiliation Networks

Nodes and affiliations

Affiliation networks in NetworkX

Projections

Summary

References

The Small Scale - Nodes and Centrality

The Small Scale - Nodes and Centrality

Centrality – finding key nodes

Bridges, brokers, and bottlenecks – betweenness centrality

Hubs – eigenvector centrality

Closeness centrality

Local clustering

Summary

References

The Big Picture - Describing Networks

The Big Picture - Describing Networks

The global structure of networks

Diameter and mean shortest path

Global clustering

Measuring resilience

Centralization and inequality

Summary

References

In-Between - Communities

In-Between - Communities

Communities – networks within networks

Community detection in NetworkX

Cliques

K-cores

Summary

References

Social Networks and Going Viral

Social Networks and Going Viral

Social networks

Strong and weak ties

The small world problem

Contagion – how things spread

Summary

References

Simulation and Analysis

Simulation and Analysis

Watts-Strogatz and small worlds

Preferential attachment and heavy-tailed networks

Configuration models

Agent-based models

Summary

References

Networks in Space and Time

Networks in Space and Time

Locations and events

Networks in space

Networks in time

Summary

References

Visualization

Visualization

Beyond the hairball

The circular layout

The shell layout

The force-directed layout

Summary

Conclusion

Conclusion

The practice of network science

Learning more

Advances in network science

The impact of network science

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Appendix

Appendix

Adjacency matrices

Biadjacency matrices

Modularity

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Networks in space

Nodes are associated with specific geographic locations in many important networks, for example the following:

Electrical grids
Road networks
Airports linked by direct flights
Telecommunication lines

The edges in these networks are physical objects and have physical properties that can influence the behavior of the system represented by the network. One weight measure isn't always enough. For example, when an edge represents a fiber optic telecommunications cable, it is important to consider both the physical length of the cable and the bandwidth (capacity) of the cable. The former influences how long signals take to travel along the cable, while the latter influences how much data it can handle (and both of these influences cost!). Not to mention that a telecommunication cable is only useful if it connects two physical locations with people who want to...

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