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In [[Social Network Analysis]] (SNA) there are various measures of [[centrality]] which determine the relative importance of an actor (or node) within the network. '''Katz centrality''' was introduced by Leo Katz in 1953 and is used to measure the degree of influence of an actor in a social network.<ref name ="katz1953" /> Unlike typical centrality measures which consider only the shortest path (the [[geodesic]]) between a pair of actors, Katz centrality measures influence by taking into account the total number of [[walk (graph theory)|walks]] between a pair of actors.<ref name="hanneman2005" /> | |||
==Measuring Katz centrality == | |||
[[File:Katz example net.png|thumb|500px|right|A simple social network: the nodes represent people or actors and the edges between nodes represent some relationship between actors]] | |||
Katz centrality computes the relative influence of a node within a network by measuring the number of the immediate neighbors (first degree nodes) and also all other nodes in the network that connect to the node under consideration through these immediate neighbors. Connections made with distant neighbors are, however, penalized by an attenuation factor <math>\alpha</math>.<ref name ="aggarwal2011" /> Each path or connection between a pair of nodes is assigned a weight determined by <math>\alpha</math> and the distance between nodes as <math>\alpha^{d-1}</math>. | |||
For example, in the figure on the right, assuming that John’s centrality is being measured and that <math>\alpha = 0.5</math>. The weight assigned to each link that connects John with his immediate neighbors Jane and Bob will be <math>(0.5)^0 = 1</math>. Jose connects to John indirectly through Bob, the weight assigned to this connection (composed of two links) will be <math>(0.5)^1 = 0.5</math>. Similarly, weight assigned to the connection between Agneta and John will be <math>(0.5)^2 = 0.25</math>. | |||
==Mathematical formulation== | |||
Let A be the [[adjacency matrix]] of a network under consideration. Elements <math>(a_{ij})</math> of A are variables that take a value 1 if a node i is connected to node j and 0 otherwise. The powers of A indicate the presence (or absence) of links between two nodes through intermediaries. For instance, in matrix <math>A^3</math>, if element <math>(a_{2,12}) = 1</math>, it indicates that node 2 and node 12 are connected through some first and second degree neighbors of node 2. If <math>C_{\mathrm{Katz}}(i)</math> denotes Katz centrality of a node i, then mathematically: | |||
:<math>C_{\mathrm{Katz}}(i) = \sum_{k=1}^{\infin}\sum_{j=1}^n \alpha^k (A^k)_{ji}</math> | |||
Note that the above definition uses the fact that the element at location <math>(i,j)</math> of the adjacency matrix <math>A</math> raised to the power <math>k</math> (i.e. <math>A^k</math>) reflects the total number of <math>k</math> degree connections between nodes <math>i</math> and <math>j</math>. The value of the attenuation factor α has to be chosen such that it is smaller than the reciprocal of the absolute value of the largest [[eigenvalue]] of the adjacency matrix A.<ref name="junker2008" /> In this case the following expression can be used to calculate Katz centrality: | |||
:<math> \overrightarrow{C}_{\mathrm{Katz}} = ((I - \alpha A^T)^{-1}-I)\overrightarrow{I}</math> | |||
Here I is the identity matrix, <math>\overrightarrow{I}</math> is an identity vector of size n (n is the number of nodes) consisting of ones. <math>A^T</math> denotes the [[transposed matrix]] of A and <math>(I - \alpha A^T)^{-1}</math> denotes [[matrix inversion]] of the term <math>(I - \alpha A^T)</math>.<ref name="junker2008" /> | |||
==Applications== | |||
Katz centrality can be used to compute centrality in directed networks such as citation networks and the World Wide Web.<ref name="newman2010" /> Katz centrality is more suitable in the analysis of directed acyclic graphs where traditionally used measures like [[Eigenvector centrality]] are rendered useless.<ref name="newman2010" /> Katz centrality can also be used in estimating the relative status or influence of actors in a social network. | |||
==References== | |||
{{Reflist|refs = | |||
<ref name ="katz1953">Katz, L. (1953). A New Status Index Derived from Sociometric Index. Psychometrika, 39-43.</ref> | |||
<ref name="hanneman2005">Hanneman, R. A., & Riddle, M. (2005). Introduction to Social Network Methods. Retrieved from http://www.faculty.ucr.edu/~hanneman/nettext/index.htm (broken link)</ref> | |||
<ref name ="aggarwal2011">Aggarwal, C. C. (2011). Social Network Data Analysis. New York, NY: Springer.</ref> | |||
<ref name="junker2008">Junker, B. H., & Schreiber, F. (2008). Analysis of Biological Networks. Hoboken, NJ: John Wiley & Sons.</ref> | |||
<ref name="newman2010">Newman, M. E. (2010). Networks: An Introduction. New York, NY: Oxford University Press.</ref> | |||
}} | |||
{{DEFAULTSORT:Katz Centrality}} | |||
[[Category:Social networks]] | |||
[[Category:Network analysis]] |
Latest revision as of 09:20, 19 February 2013
In Social Network Analysis (SNA) there are various measures of centrality which determine the relative importance of an actor (or node) within the network. Katz centrality was introduced by Leo Katz in 1953 and is used to measure the degree of influence of an actor in a social network.[1] Unlike typical centrality measures which consider only the shortest path (the geodesic) between a pair of actors, Katz centrality measures influence by taking into account the total number of walks between a pair of actors.[2]
Measuring Katz centrality
Katz centrality computes the relative influence of a node within a network by measuring the number of the immediate neighbors (first degree nodes) and also all other nodes in the network that connect to the node under consideration through these immediate neighbors. Connections made with distant neighbors are, however, penalized by an attenuation factor .[3] Each path or connection between a pair of nodes is assigned a weight determined by and the distance between nodes as .
For example, in the figure on the right, assuming that John’s centrality is being measured and that . The weight assigned to each link that connects John with his immediate neighbors Jane and Bob will be . Jose connects to John indirectly through Bob, the weight assigned to this connection (composed of two links) will be . Similarly, weight assigned to the connection between Agneta and John will be .
Mathematical formulation
Let A be the adjacency matrix of a network under consideration. Elements of A are variables that take a value 1 if a node i is connected to node j and 0 otherwise. The powers of A indicate the presence (or absence) of links between two nodes through intermediaries. For instance, in matrix , if element , it indicates that node 2 and node 12 are connected through some first and second degree neighbors of node 2. If denotes Katz centrality of a node i, then mathematically:
Note that the above definition uses the fact that the element at location of the adjacency matrix raised to the power (i.e. ) reflects the total number of degree connections between nodes and . The value of the attenuation factor α has to be chosen such that it is smaller than the reciprocal of the absolute value of the largest eigenvalue of the adjacency matrix A.[4] In this case the following expression can be used to calculate Katz centrality:
Here I is the identity matrix, is an identity vector of size n (n is the number of nodes) consisting of ones. denotes the transposed matrix of A and denotes matrix inversion of the term .[4]
Applications
Katz centrality can be used to compute centrality in directed networks such as citation networks and the World Wide Web.[5] Katz centrality is more suitable in the analysis of directed acyclic graphs where traditionally used measures like Eigenvector centrality are rendered useless.[5] Katz centrality can also be used in estimating the relative status or influence of actors in a social network.
References
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