@ -19,20 +19,20 @@ Network motifs are recurring, significant patterns of interconnections in the ne
Recurrence of motif represents it occurs with high frequency. We allow overlapping of motifs.
Recurrence of motif represents it occurs with high frequency. We allow overlapping of motifs.
Significance of a motif means it is more frequent than expected. The key idea here is we say subgraphs that occur in a real network much more often than in a random network have functional significance. Significance can be measured using Z-score which is defined as: \begin{equation} Z_{i} = \frac{N_{i}^{real} - \overline N_{i}^{rand}}{std(N_{i}^{rand})} \end{equation} <br>
Significance of a motif means it is more frequent than expected. The key idea here is we say subgraphs that occur in a real network much more often than in a random network have functional significance. Significance can be measured using Z-score which is defined as: \begin{equation} Z_{i} = \frac{N_{i}^{real} - \overline N_{i}^{rand}}{std(N_{i}^{rand})} \end{equation} <br>
where $N_{i}^{real}$ is #(subgraphs of type i) in network $G^{real}$ and $N_{i}^{rand}$ is #(subgraphs of type i) in randomized network $G^{rand}$.
where $$N_{i}^{real}$$ is #(subgraphs of type i) in network $$G^{real}$$ and $$N_{i}^{rand}$$ is #(subgraphs of type i) in randomized network $$G^{rand}$$.
Network significance profile (SP) is defined as: \begin{equation} SP_{i} = \frac{Z_{i}}{\sqrt{\sum_{j} {Z_j^{2}}}} \end{equation} where SP is a vector of normalized Z-scores.
Network significance profile (SP) is defined as: \begin{equation} SP_{i} = \frac{Z_{i}}{\sqrt{\sum_{j} {Z_j^{2}}}} \end{equation} where SP is a vector of normalized Z-scores.
### Configuration Model
### Configuration Model
Configuration model is a random graph with a given degree sequence $k_1$, $k_2$, ..., $k_N$ which can be used as a "null" model and then compared with real network. Configuration model can be generated in an easy way as shown in Figure 2.
Configuration model is a random graph with a given degree sequence $$k_1$$, $$k_2$$, ..., $$k_N$$ which can be used as a "null" model and then compared with real network. Configuration model can be generated in an easy way as shown in Figure 2.
Just knowing if a certain subgraph exists in a graph is a hard computational problem. Also, computation time grows exponentially as the size of the motif/graphlet increases.
Just knowing if a certain subgraph exists in a graph is a hard computational problem. Also, computation time grows exponentially as the size of the motif/graphlet increases.
### ESU Algorithm
### ESU Algorithm
Exact Subgraph Enumeration (ESU) Algorithm involves two sets, while $V_{subgraph}$ contains nodes in currently constructed subgraph, and $V_{extension}$ is a set of candidate nodes to extend the motif. The basic idea of ESU is firstly starting with a node v, then adding nodes u to $V_{extension}$ set when u's node id is larger than that of v, and u may only be neighbored to some newly added node w but not of any node already in $V_{subgraph}$.
Exact Subgraph Enumeration (ESU) Algorithm involves two sets, while $$V_{subgraph}$$ contains nodes in currently constructed subgraph, and $$V_{extension}$$ is a set of candidate nodes to extend the motif. The basic idea of ESU is firstly starting with a node v, then adding nodes u to $$V_{extension}$$ set when u's node id is larger than that of v, and u may only be neighbored to some newly added node w but not of any node already in $$V_{subgraph}$$.
ESU is implemented as a recursive function, Figure 3 shows the pseudocode of this algorithm:
ESU is implemented as a recursive function, Figure 3 shows the pseudocode of this algorithm: