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Graph Machine Learning

You're reading from   Graph Machine Learning Take graph data to the next level by applying machine learning techniques and algorithms

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Product type Paperback
Published in Jun 2021
Publisher Packt
ISBN-13 9781800204492
Length 338 pages
Edition 1st Edition
Languages
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Authors (3):
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Aldo Marzullo Aldo Marzullo
Author Profile Icon Aldo Marzullo
Aldo Marzullo
Claudio Stamile Claudio Stamile
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Claudio Stamile
Enrico Deusebio Enrico Deusebio
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Enrico Deusebio
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Toc

Table of Contents (15) Chapters Close

Preface 1. Section 1 – Introduction to Graph Machine Learning
2. Chapter 1: Getting Started with Graphs FREE CHAPTER 3. Chapter 2: Graph Machine Learning 4. Section 2 – Machine Learning on Graphs
5. Chapter 3: Unsupervised Graph Learning 6. Chapter 4: Supervised Graph Learning 7. Chapter 5: Problems with Machine Learning on Graphs 8. Section 3 – Advanced Applications of Graph Machine Learning
9. Chapter 6: Social Network Graphs 10. Chapter 7: Text Analytics and Natural Language Processing Using Graphs 11. Chapter 8:Graph Analysis for Credit Card Transactions 12. Chapter 9: Building a Data-Driven Graph-Powered Application 13. Chapter 10: Novel Trends on Graphs 14. Other Books You May Enjoy

Graph properties

As we have already learned, a graph is a mathematical model that is used for describing relations between entities. However, each complex network presents intrinsic properties. Such properties can be measured by particular metrics, and each measure may characterize one or several local and global aspects of the graph.

In a graph for a social network such as Twitter, for example, users (represented by the nodes of the graph) are connected to each other. However, there are users that are more connected than others (influencers). On the Reddit social graph, users with similar characteristics tend to group into communities.

We have already mentioned some of the basic features of graphs, such as the number of nodes and edges in a graph, which constitute the size of the graph itself. Those properties already provide a good description of the structure of a network. Think about the Facebook graph, for example: it can be described in terms of the number of nodes and edges. Such numbers easily allow it to be distinguished from a much smaller network (for example, the social structure of an office) but fail to characterize more complex dynamics (for example, how similar nodes are connected). To this end, more advanced graph-derived metrics can be considered, which can be grouped into four main categories, outlined as follows:

  • Integration metrics: These measure how nodes tend to be interconnected with each other.
  • Segregation metrics: These quantify the presence of groups of interconnected nodes, known as communities or modules, within a network.
  • Centrality metrics: These assess the importance of individual nodes inside a network.
  • Resilience metrics: These can be thought of as a measure of how much a network is able to maintain and adapt its operational performance when facing failures or other adverse conditions.

Those metrics are defined as global when expressing a measure of an overall network. On the other hand, local metrics measure values of individual network elements (nodes or edges). In weighted graphs, each property may or may not account for the edge weights, leading to weighted and unweighted metrics.

In the following section, we describe some of the most commonly used metrics that measure global and local properties. For simplicity, unless specified differently in the text, we illustrate the global unweighted version of the metric. In several cases, this is obtained by averaging the local unweighted properties of the node.

Integration metrics

In this section, some of the most frequently used integration metrics will be described.

Distance, path, and shortest path

The concept of distance in a graph is often related to the number of edges to traverse in order to reach a target node from a given source node.

In particular, consider a source node and a target node . The set of edges connecting node to node is called a path. When studying complex networks, we are often interested in finding the shortest path between two nodes. A shortest path between a source node and a target node is the path having the lowest number of edges compared to all the possible paths between and . The diameter of a network is the number of edges contained in the longest shortest path among all possible shortest paths.

Take a look at the following screenshot. There are different paths to reach Tokyo from Dublin. However, one of them is the shortest (the edges on the shortest path are highlighted):

Figure 1.14 – The shortest path between two nodes

Figure 1.14 – The shortest path between two nodes

The shortest_path function of the networkx Python library enables users to quickly compute the shortest path between two nodes in a graph. Consider the following code, in which a seven-node graph is created by using networkx:

G = nx.Graph()
nodes = {1:'Dublin',2:'Paris',3:'Milan',4:'Rome',5:'Naples',
         6:'Moscow',7:'Tokyo'}
G.add_nodes_from(nodes.keys())
G.add_edges_from([(1,2),(1,3),(2,3),(3,4),(4,5),(5,6),(6,7),(7,5)])

The shortest path between a source node (for example, 'Dublin', identified by the key 1) and a target node (for example, 'Tokyo', identified by the key 7) can be obtained as follows:

path = nx.shortest_path(G,source=1,target=7)

This should output the following:

[1,3,4,5,6]

Here, [1,3,4,5,7] are the nodes contained in the shortest path between 'Tokyo' and 'Dublin'.

Characteristic path length

The characteristic path length is defined as the average of all the shortest path lengths between all possible pair of nodes. If is the average path length between the node and all the other nodes, the characteristic path length is computed as follows:

Here, is the set of nodes in the graph and represents its order. This is one of the most commonly used measures of how efficiently information is spread across a network. Networks having shorter characteristic path lengths promote the quick transfer of information and reduce costs. Characteristic path length can be computed through networkx using the following function:

nx.average_shortest_path_length(G)

This should give us the following:

2.1904761904761907

However, this metric cannot be always defined since it is not possible to compute a path among all the nodes in disconnected graphs. For this reason, network efficiency is also widely used.

Global and local efficiency

Global efficiency is the average of the inverse shortest path length for all pairs of nodes. Such a metric can be seen as a measure of how efficiently information is exchanged across a network. Consider that is the shortest path between a node and a node . The network efficiency is defined as follows:

Efficiency is at a maximum when a graph is fully connected, while it is minimal for completely disconnected graphs. Intuitively, the shorter the path, the lower the measure.

The local efficiency of a node can be computed by considering only the neighborhood of the node in the calculation, without the node itself. Global efficiency is computed in networkx using the following command:

nx.global_efficiency(G)

The output should be as follows:

0.6111111111111109

Average local efficiency is computed in networkx using the following command:

nx.local_efficiency(G)

The output should be as follows:

0.6666666666666667

In the following screenshot, two examples of graphs are depicted. As observed, a fully connected graph on the left presents a higher level of efficiency compared to a circular graph on the right. In a fully connected graph, each node can be reached from any other node in the graph, and information is exchanged rapidly across the network. However, in a circular graph, several nodes should instead be traversed to reach the target node, making it less efficient:

Figure 1.15 – Global efficiency of a fully connected graph (left) and a circular graph (right)

Figure 1.15 – Global efficiency of a fully connected graph (left) and a circular graph (right)

Integration metrics well describe the connection among nodes. However, more information about the presence of groups can be extracted by considering segregation metrics.

Segregation metrics

In this section, some of the most common segregation metrics will be described.

Clustering coefficient

The clustering coefficient is a measure of how much nodes cluster together. It is defined as the fraction of triangles (complete subgraph of three nodes and three edges) around a node and is equivalent to the fraction of the node's neighbors that are neighbors of each other. A global clustering coefficient is computed in networkx using the following command:

nx.average_clustering(G)

This should output the following:

0.6666666666666667

The local clustering coefficient is computed in networkx using the following command:

nx.clustering(G)

This should output the following:

{1: 1.0,
 2: 1.0,
 3: 0.3333333333333333,
 4: 0,
 5: 0.3333333333333333,
 6: 1.0,
 7: 1.0}

The output is a Python dictionary containing, for each node (identified by the respective key), the corresponding value. In the graph represented in Figure 1.16, two clusters of nodes can be easily identified. By computing the clustering coefficient for each single node, it can be observed that Rome has the lowest value. Tokyo and Moscow, as well as Paris and Dublin, are instead very well connected within their respective groups (notice the size of each node is drawn proportionally to each node's clustering coefficient). The graph can be seen in the following screenshot:

Figure 1.16 – Local clustering coefficient representation

Figure 1.16 – Local clustering coefficient representation

Transitivity

A common variant of the clustering coefficient is known as transitivity. This can simply be defined as the ratio between the observed number of closed triplets (complete subgraph with three nodes and two edges) and the maximum possible number of closed triplets in the graph. Transitivity can be computed using networkx, as follows:

nx.transitivity(G)

The output should be as follows:

0.5454545454545454

Modularity

Modularity was designed to quantify the division of a network in aggregated sets of highly interconnected nodes, commonly known as modules, communities, groups, or clusters. The main idea is that networks having high modularity will show dense connections within the module and sparse connections between modules.

Consider a social network such as Reddit: members of communities related to video games tend to interact much more with other users in the same community, talking about recent news, favorite consoles, and so on. However, they will probably interact less with users talking about fashion. Differently from many other graph metrics, modularity is often computed by means of optimization algorithms.

Modularity in networkx is computed using the modularity function of the networkx.algorithms.community module, as follows:

import networkx.algorithms.community as nx_comm
nx_comm.modularity(G, communities=[{1,2,3}, {4,5,6,7}])

Here, the second argument—communities—is a list of sets, each representing a partition of the graph. The output should be as follows:

0.3671875

Segregation metrics help to understand the presence of groups. However, each node in a graph has its own importance. To quantify it, we can use centrality metrics.

Centrality metrics

In this section, some of the most common centrality metrics will be described.

Degree centrality

One of the most common and simple centrality metrics is the degree centrality metric. This is directly connected with the degree of a node, measuring the number of incident edges on a certain node .

Intuitively, the more a node is connected to an other node, the more its degree centrality will assume high values. Note that, if a graph is directed, the in-degree centrality and out-degree centrality will be considered for each node, related to the number of incoming and outcoming edges, respectively. Degree centrality is computed in networkx by using the following command:

nx.degree_centrality(G)

The output should be as follows:

{1: 0.3333333333333333, 2: 0.3333333333333333, 3: 0.5, 4: 0.3333333333333333, 5: 0.5, 6: 0.3333333333333333, 7: 0.3333333333333333}

Closeness centrality

The closeness centrality metric attempts to quantify how much a node is close (well connected) to other nodes. More formally, it refers to the average distance of a node to all other nodes in the network. If is the shortest path between node and node , the closeness centrality is defined as follows:

Here, V is the set of nodes in the graph. Closeness centrality can be computed in networkx using the following command:

nx.closeness_centrality(G)

The output should be as follows:

{1: 0.4, 2: 0.4, 3: 0.5454545454545454, 4: 0.6, 5: 0.5454545454545454, 6: 0.4, 7: 0.4}

Betweenness centrality

The betweenness centrality metric evaluates how much a node acts as a bridge between other nodes. Even if poorly connected, a node can be strategically connected, helping to keep the whole network connected.

If is the total number of shortest paths between node and node and is the total number of shortest paths between and passing through node , then the betweenness centrality is defined as follows:

If we observe the formula, we can notice that the higher the number of shortest paths passing through node , the higher the value of the betweenness centrality. Betweenness centrality is computed in networkx by using the following command:

nx.betweenness_centrality(G)

The output should be as follows:

{1: 0.0, 2: 0.0, 3: 0.5333333333333333, 4: 0.6, 5: 0.5333333333333333, 6: 0.0, 7: 0.0}

In Figure 1.17, we illustrate the difference between degree centrality, closeness centrality, and betweenness centrality. Milan and Naples have the highest degree centrality. Rome has the highest closeness centrality since it is the closest to any other node. It also shows the highest betweenness centrality because of its crucial role in connecting the two visible clusters and keeping the whole network connected.

You can see the differences here:

Figure 1.17 – Degree centrality (left), closeness centrality (center), and betweenness centrality (right)

Figure 1.17 – Degree centrality (left), closeness centrality (center), and betweenness centrality (right)

Centrality metrics allow us to measure the importance of a node inside the network. Finally, we will mention resilience metrics, which enable us to measure the vulnerability of a graph.

Resilience metrics

There are several metrics that measure a network's resilience. Assortativity is one of the most used.

Assortativity coefficient

Assortativity is used to quantify the tendency of nodes being connected to similar nodes. There are several ways to measure such correlations. One of the most commonly used methods is the Pearson correlation coefficient between the degrees of directly connected nodes (nodes on two opposite ends of a link). The coefficient assumes positive values when there is a correlation between nodes of a similar degree, while it assumes negative values when there is a correlation between nodes of a different degree. Assortativity using the Pearson correlation coefficient is computed in networkx by using the following command:

nx.degree_pearson_correlation_coefficient(G)

The output should be as follows:

-0.6

Social networks are mostly assortative. However, the so-called influencers (famous singers, football players, fashion bloggers) tend to be followed (incoming edges) by several standard users, while tending to be connected with each other and showing a disassortative behavior.

It is important to remark that the previously presented properties are a subset of all the possible metrics used to describe graphs. A wider set of metrics and algorithms can be found at https://networkx.org/documentation/stable/reference/algorithms/.

You have been reading a chapter from
Graph Machine Learning
Published in: Jun 2021
Publisher: Packt
ISBN-13: 9781800204492
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