flowbet: Calculate Flow Betweenness Scores of Network Positions

A vector of centrality scores.

The (“raw,” or unnormalized) flow betweenness of a vertex, \(v \in V(G)\), is defined by Freeman et al. (1991) as $$ C_F(v) = \sum_{i,j : i \neq j, i \neq v, j \neq v} \left(f(i,j,G) - f(i,j,G\setminus v)\right),$$ where \(f(i,j,G)\) is the maximum flow from \(i\) to \(j\) within \(G\) (under the assumption of infinite vertex capacities, finite edge capacities, and non-simultaneity of pairwise flows). Intuitively, unnormalized flow betweenness is simply the total maximum flow (aggregated across all pairs of third parties) mediated by \(v\).

The above flow betweenness measure is computed by flowbet when cmode=="rawflow". In some cases, it may be desirable to normalize the raw flow betweenness by the total maximum flow among third parties (including \(v\)); this leads to the following normalized flow betweenness measure: $$ C'_F(v) = \frac{\sum_{i,j : i \neq j, i \neq v, j \neq v} \left(f(i,j,G) - f(i,j,G\setminus v)\right)}{\sum_{i,j : i \neq j, i \neq v, j \neq v} f(i,j,G)}.$$ This variant can be selected by setting cmode=="normflow".

Finally, it may be noted that the above normalization (from Freeman et al. (1991)) is rather different from that used in the definition of shortest-path betweenness, which normalizes within (rather than across) third-party dyads. A third flow betweenness variant has been suggested by Koschutzki et al. (2005) based on a normalization of this type: $$ C''_F(v) = \sum_{i,j : i \neq j, i \neq v, j \neq v} \frac{ \left(f(i,j,G) - f(i,j,G\setminus v)\right)}{f(i,j,G)}$$ where 0/0 flow ratios are treated as 0 (as in shortest-path betweenness). Setting cmode=="fracflow" selects this variant.