Difference between revisions of "Identifying influential bloggers: WSDM 2008"

Citation

Nitin Agarwal, Huan Liu, Lei Tang, Philip S. Yu, "Identifying the Influential Bloggers in a Community", Proceedings of the International Conference on Web Search and Web Data Mining (WSDM), 2008.

Online version

Available at Citesteer

Summary

This paper aims at identifying most influential bloggers in a blogging community. The paper first proposes some metric for assessing how influential a blog post is. Then the authors perform some experiments on blogs from few blog sites and qualitatively evaluate their results.

What makes a Blog influential

Recognition: An influential blog post is recognized by many, which can be judged by the number of in-links (\iota), i.e. the number of other posts referencing the particular post.
Activity Generation: A blog post that generates more activity is supposedly more influential. This is measured by the number of comments made on the blog post (\gamma).
Novelty: Novel ideas are supposed to be more influential [1]. A post that references more other posts (or has more out-links) is supposed to have lesser novel ideas. So novelty can be taken as negatively correlated with the number of out-links (\theta) Eloquence: More eloquent posts are more influential [1]. Authors use the length of the blog post (\lambda) as a measure of eloquence.

The Math behind this

Reader Measure

Given the full set of comments to a blog, the authors construct a directed reader graph ${\displaystyle G_{R}:=(V_{R},E_{R})}$. Each node ${\displaystyle r_{a}\epsilon V_{R}}$ is a reader, and an edge ${\displaystyle e_{R}(r_{b},r_{a})\epsilon E_{R}}$ exists if ${\displaystyle r_{b}}$ mentions ${\displaystyle r_{a}}$ in one of ${\displaystyle r_{b}}$’s comments. The weight on an edge, ${\displaystyle W_{R}(r_{b},r_{a})}$, is the ratio between the number of times ${\displaystyle r_{b}}$ mentions ${\displaystyle r_{a}}$ against all times ${\displaystyle r_{b}}$ mentions other readers (including ${\displaystyle r_{a}}$). The authors compute reader authority using a ranking algorithm, shown in Equation 1, where ${\displaystyle |R|}$ denotes the total number of readers of the blog, and d is the damping factor.

${\displaystyle A(r_{a})=d*1/|R|+(1-d)\Sigma W_{R}(r_{b},r_{a})*A(r_{b})............(1)}$
${\displaystyle RM(w_{k})=\Sigma tf(w_{k},c_{i})*A(r_{a})...............................(2)}$
The reader measure of a word ${\displaystyle w_{k}}$, denoted by ${\displaystyle RM(w_{k})}$, is given in Equation 2, where ${\displaystyle tf(w_{k},c_{i})}$ is the term frequency of word ${\displaystyle w_{k}}$ in comment ${\displaystyle c_{i}}$.

Quotation Measure

For the set of comments associated with each blog post, the authors construct a directed acyclic quotation graph ${\displaystyle G_{Q}:=(V_{Q},E_{Q})}$. Each node ${\displaystyle c_{i}\epsilon V_{Q}}$ is a comment, and an edge ${\displaystyle (c_{j},c_{i})\epsilon E_{Q}}$ indicates ${\displaystyle c_{j}}$ quoted sentences from ${\displaystyle c_{i}}$. The weight on an edge, ${\displaystyle W_{Q}(c_{j},c_{i})}$, is 1 over the number of comments that c_j ever quoted. The authors derive the quotation degree ${\displaystyle D(c_{i})}$ of a comment ${\displaystyle c_{i}}$ using Equation 3. A comment that is not quoted by any other comment receives a quotation degree of ${\displaystyle 1/|C|}$ where ${\displaystyle |C|}$ is the number of comments associated with the given post. ${\displaystyle D(c_{i})=1/|C|+\Sigma W_{Q}(c_{j},c_{i})*D(c_{j})...........(3)}$
${\displaystyle Q_{M}(w_{k})=\Sigma tf(w_{k},c_{i})*D(c_{i})..................(4)}$
The quotation measure of a word ${\displaystyle w_{k}}$, denoted by ${\displaystyle QM(w_{k})}$, is given in Equation 4. Word ${\displaystyle w_{k}}$ appears in comment ${\displaystyle c_{i}}$.

Topic Measure

Given the set of comments associated with each blog post, the authors group these comments into topic clusters using a Single-Pass Incremental Clustering algorithm presented in [1]. The authors conjecture that a hotly discussed topic has a large number of comments all close to the topic cluster centroid. Thus they propose Equation 5 to compute the importance of a topic cluster, where ${\displaystyle |c_{i}|}$ is the length of comment ${\displaystyle c_{i}}$ in number of words, ${\displaystyle C}$ is the set of comments, and ${\displaystyle sim(c_{i},t_{u})}$ is the cosine similarity between comment ${\displaystyle c_{i}}$ and the centroid of topic cluster ${\displaystyle t_{u}}$.

${\displaystyle T(t_{u})=1/\Sigma |c_{j}|*\Sigma |c_{i}|*sim(c_{i},t_{u})......................(5)}$
${\displaystyle TM(w_{k})=\Sigma tf(w_{k},c_{i})*T(t_{u})......................................(6)}$

Equation 6 defines the topic measure of a word ${\displaystyle w_{k}}$, denoted by ${\displaystyle TM(w_{k})}$. Comment ${\displaystyle c_{i}}$ is clustered into topic cluster ${\displaystyle t_{u}}$.

Overall Word Representativeness or Importance Score

The representativeness score of a word ${\displaystyle Rep(w_{k})}$ is the combination of reader-, quotation- and topic- measures in ReQuT model. The three measures are first normalized independently based on their corresponding maximum values and then combined linearly to derive ${\displaystyle Rep(w_{k})}$ using Equation 7. In this equation ${\displaystyle \alpha }$, ${\displaystyle \beta }$ and ${\displaystyle \gamma }$ are the coefficients (0 ≤ ${\displaystyle \alpha }$, ${\displaystyle \beta }$, ${\displaystyle \gamma }$ ≤ 1.0 and ${\displaystyle \alpha }$ + ${\displaystyle \beta }$ + ${\displaystyle \gamma }$ = 1.0).

${\displaystyle Rep(w_{k})=\alpha *RM(w_{k})+\beta *QM(w_{k})+\gamma *TM(w_{k}).......................(7)}$

Sentence Selection Criteria

Density Based Selection: Based on representativeness score of keywords and the distance between two keywords in a sentence. In equation 8, K is the total number of keywords contained in i^th sentence ${\displaystyle s_{i}}$, ${\displaystyle Score(w_{j})}$ is the representativeness score of keyword ${\displaystyle w_{j}}$, and ${\displaystyle distance(w_{j},w_{j}+1)}$ is the number of non-keywords (including stopwords) between the two adjacent keywords ${\displaystyle w_{j}}$ and ${\displaystyle w_{j}+1}$ in ${\displaystyle s_{i}}$.

${\displaystyle Score(s_{i})=1/K*(K+1)*\Sigma Score(w_{j})*Score(w_{j+1})/distance(w_{j},w_{j+1})^{2}............................(8)}$

Summation Based Selection: Based on the number of keywords contained in a sentence. In equation 9, ${\displaystyle |s_{i}|}$ is the length of sentence ${\displaystyle s_{i}}$ in number of words (including stopwords), and ${\displaystyle tau}$ (${\displaystyle tau}$ > 0) is a parameter to flexibly control the contribution of a word’s representativeness score.

${\displaystyle Rep(s_{i})=1/|s_{i}|*(\Sigma Rep(w_{k})^{\tau })^{1/\tau }................................(9)}$

Results

Two metrics were used: R-Precision and NDCG. NDCG is described in [2].

References

[1] D. Shen, Q. Yang, J.-T. Sun, and Z. Chen. Thread detection in dynamic text message streams. In Proc. of SIGIR ’06, pages 35–42, Seattle, Washington, 2006.
[2] K. Jrvelin and J. Keklinen. IR evaluation methods for retrieving highly relevant documents. In Proc. of SIGIR ’00, pages 41–48, Athens, Greece, 2000.