Difference between revisions of "Blog summarization: CIKM 2007"

Citation

Meishan Hu, Aixin Sun and Ee-Peng Lim, "Comments-oriented blog summarization by sentence extraction ", Proceedings of the sixteenth ACM conference on Conference on information and knowledge management, 2007

Online version

[1]

Summary

This paper aims at blog summarization by identifying important sentences of a blog by analyzing the comments made to it, and then extracting these sentences to present a summary of the blog. Authors use a Reader-Quotation-Topic model to give representativeness score to different words in user comments. Then, “significant” sentences from the blog are selected based on two methods: Density-based Selection and Summation-based selection. Authors employed humans to create summaries of the blogs to evaluate their method against. Please see the dataset page for information about dataset. Below, is presented a closer look at Reader-Quotation-Topic model and the two sentence-selection methodologies along with the results of the experiments.

Reader-Quotation-Topic (ReQuT) model

Each word is given a Reader, a Quotation and a Topic measure. The motivation is that words written by “authoritative” readers, or the ones found in comments which are quoted in other comments, or those that relate to mostly discussed topics, are important than others. So ReQuT scores are given to each word, and the overall importance of that word is judged by a weighted sum of the ReQuT scores.

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).

<math>Rep(w_k) = \alpha * RM(w_k) + \beta * QM(w_k) + \gamma * TM(w_k).......................(7)