Difference between revisions of "Snapshot"

Latest revision as of 15:53, 4 April 2011

Snapshot: Consider two snapshots of the network at different points in time. For each k, consider the set of all individuals who are k-exposed in the ﬁrst snapshot. Let ps(k) be the fraction of individuals in this set who have become adopters by the time of the second snapshot.

Figure 2 shows the shape of influence curves for the snapshot definitions using the Wikipedia data:

As with ordinal time, it is now useful to deﬁne $p_{s}\left(k\right)$ as the ratio of two quantities, $p_{s}\left(k\right)=n_{s}\left(k\right)/d_{s}\left(k\right)$ , where $d_{s}\left(k\right)$ is the number of triples (u;C; k) for which u was k-exposed to C at time t1, and $n_{s}\left(k\right)$ is the number of triples (u,C,k) for which u was k-exposed to C at time t1, and then joined C between t1 and t2.

@@ Line 1: / Line 1: @@
 Snapshot: Consider two snapshots of the network at different points in time. For each k, consider the set of all individuals who are [[k-exposed]] in the ﬁrst snapshot. Let ps(k) be the fraction of individuals in this set who have become adopters by the time of the second snapshot.
+Figure 2 shows the shape of influence curves for the snapshot definitions using the Wikipedia data:
+[[File:snapshot.jpg]]
+As with ordinal time, it is now useful to deﬁne <math>p_{s}\left ( k \right )</math> as the ratio of two quantities, <math>p_{s}\left ( k \right )=n_{s}\left ( k \right )/d_{s}\left ( k \right )</math>, where <math>d_{s}\left ( k \right )</math> is the number of triples (u;C; k) for which u was k-exposed to C at time t1, and <math>n_{s}\left ( k \right )</math> is the number of triples (u,C,k) for which u was k-exposed to C at time t1, and then joined C between t1 and t2.

Difference between revisions of "Snapshot"

Latest revision as of 15:53, 4 April 2011

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