Difference between revisions of "Xufei Wang, ICDM, 2010"

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The singular value decomposition of user-tag network M is given by <math>M= U\Sigma V^{T}</math>, where columns of U and V are the left and right singular vectors and <math>\Sigma </math> is the diagonal matrix whose elements are singular values.
 
The singular value decomposition of user-tag network M is given by <math>M= U\Sigma V^{T}</math>, where columns of U and V are the left and right singular vectors and <math>\Sigma </math> is the diagonal matrix whose elements are singular values.
 +
 +
\vec{u}_i(\vec{t}_1,\vec{t}_2,...,\vec{t}_m)=u_i(t_1,t_2,...t_n)V
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 +
S_u(u_i,u_j)=\frac{\vec{u}_i \vec{u}_j}{\left \| \vec{u}_i \right \| \left \| \vec{u}_j \right \|}
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S_t(t_i,t_j)=\frac{\vec{t}_i \vec{t}_j}{\left \| \vec{t}_i \right \| \left \| \vec{t}_j \right \|}
  
 
== Experimental Result ==
 
== Experimental Result ==
  
 
== Related papers ==
 
== Related papers ==

Revision as of 23:44, 27 March 2011

Citation

Xufei Wang. 2010. Discovering Overlapping Groups in Social Media, the 10th IEEE International Conference on Data Mining (ICDM 2010).

Online Version

http://dmml.asu.edu/users/xufei/Papers/ICDM2010.pdf

Databases

BlogCatalog [1]

Delicious [2]

Summary

In this paper, the authors propose a novel co-clustering framework, which takes advantage of networking information between users and tags in social media, to discover these overlapping communities. The basic ideas are:

  • To discover overlapping communities in social media. Diverse interests and interactions that human beings can have in online social life suggest that one person often belongs more than one community.
  • To use user-tag subscription information instead of user-user links. Metadata such as tags become an important source in measuring the user-user similarity. The paper shows that more accurate community structures can be obtained by scrutinizing tag information.
  • To obtain clusters containing users and tags simultaneously. Existing co-clustering methods cluster users/tags separately. Thus, it is not clear which user cluster corresponds to which tag cluster. But the proposed method is able to find out user/tag group structure and their correspondence

Problem Statement

In this paper, the concept of community is generalized to include both users and tags. Tags of a community imply the major concern of people within it.

Let denote the user set, the tay set. A community is a subset of user and tags, where k is the number of communities. As mentioned above, communities usually overlap, i.e., .On the other hand, users and their subscribed tags form a user-tag matrix M, in which each entry indicates whether user subscribes to tag . So it is reasonable to view a user as a sparse vector of tags, and each tag as a sparse vector of users.

Given notations above, the overlapping co-clustering problem can be stated formally as follows:

Input:

  • A user-tag subscription matrix , where and are the numbers of users and tags.
  • The number of communities k.

Output:

  • k overlapping communities which consist of both users and tags.

Brief description of the method

Communities that aggregate similar users and tags together can be detected by maximizing intra-cluster similarity, which is shown below: where k is the number of communities, x is the edges and c is the centroid of community. This formulation can be solved by a k-means variant.

This paper uses different methods to solve the problem of overlapping communities:


A. Independent Learning

If two tags are different, their similarity can be defined as 0, and 1 if they are the same. their cosine similarity can be rewritten as:

B. Normalized Learning

Let denote the degree of the user ,and represent the degree of tag in a user-tag network. their cosine similarity can be rewritten as:

C. Correlational Learning

The singular value decomposition of user-tag network M is given by , where columns of U and V are the left and right singular vectors and is the diagonal matrix whose elements are singular values.

\vec{u}_i(\vec{t}_1,\vec{t}_2,...,\vec{t}_m)=u_i(t_1,t_2,...t_n)V

S_u(u_i,u_j)=\frac{\vec{u}_i \vec{u}_j}{\left \| \vec{u}_i \right \| \left \| \vec{u}_j \right \|}

S_t(t_i,t_j)=\frac{\vec{t}_i \vec{t}_j}{\left \| \vec{t}_i \right \| \left \| \vec{t}_j \right \|}

Experimental Result

Related papers