generative model to construct blog and post networks in blogosphere
DESCRIPTION
Generative Model To Construct Blog and Post Networks In Blogosphere. Masters Thesis Defense Amit Karandikar Advisor: Dr. Anupam Joshi Committee: Dr. Finin, Dr. Yesha, Dr. Oates Date: 1 st May 2007 Time: 9:30 am Place: ITE 325B. http://prefuse.org/gallery/. Outline. Introduction - PowerPoint PPT PresentationTRANSCRIPT
Masters Thesis DefenseAmit Karandikar
Advisor: Dr. Anupam JoshiCommittee: Dr. Finin, Dr. Yesha, Dr. Oates
Date: 1st May 2007Time: 9:30 amPlace: ITE 325B
Generative Model To Construct Blog Generative Model To Construct Blog and Post Networks and Post Networks
In BlogosphereIn Blogosphere
http://prefuse.org/gallery/
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Outline
• Introduction
• Motivation
• Thesis Contribution
• Interactions in Blogosphere
• Proposed Model
• Experiments and Results
• Conclusion
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Generative model: A generative model is a model for randomly / systematically generating the observed data using some input parameters.Parameters could be latent or input to the model.
Blogosphere: Blogosphere is the collective term encompassing all blogs linked together forming as a community or social network.
Blog network: Network formed by considering each blog single node.
Post Network: Network formed considering post as a node; ignoring its parent blog.
IntroductionGenerative Model To Construct Blog and Post Networks In
Blogosphere
finin.livejournal.comjoshi.blogspot.com
oates.myspace.comyesha.blogspot.com
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Basics ..
Graphs are everywhere .. and so are Power laws!!
Internet Mapping Project [lumeta.com]
Friendship Network [Moody ‘01]
In simple words, power law can be explained by “rich get richer phenomenon” OR “20% of the population holds 80% of the wealth”
Considering web as a graph:
Scale-free network: Structure and properties independent of network size
Few high connectivity node (hubs)
http://www.prefuse.org/gallery/
Properties of interest (graph theory)
Average degree of node, degree distribution, degree correlation, distribution of strongly/weakly connected components, clustering coefficient and reciprocity
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MotivationWhy simulate blog graphs?
• Reduce time to generate data- crawling the blogosphere over a few weeks- sampling the right blogs to get a representative sample
• Reduce time in preprocessing and data cleaning- removing links pointing outside the dataset, outside the time frame- splog removal [1]
• Generate graphs of different properties\sizes- average degree of node, degree distributions
• Testing of new algorithms for blog graphs- e.g. spread of influence in blogosphere [2], community detection [3]
• Extrapolation- how will fast growth affect the blogosphere properties?- how does this affect the connected components?
[1] Kolari et al “Svms for the blogosphere: Blog identification and splog detection,” in AAAI Spring Symposium on Computational Approaches to Analyzing Weblogs, 2006.
[2] Java et al “Modeling the spread of influence on the blogosphere,” tech. rep., University of Maryland, Baltimore County, March 2006.
[3] Lin et al “Discovery of Blog Communities based on Mutual Awareness
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Thesis Contribution
1. To propose a generative model for a blog-blog network using preferential attachment and uniform random attachment by modeling the interactions among bloggers
2. To generate post-post network as part of the generative model for blog graphs.
3. Compare the properties of the simulated blog and post networks with the properties observed in the available real blog datasets.
DatasetsWorkshop on the Weblogging Ecosystem (WWE 2006)http://weblogging2006.blogspot.com/International Conference on Weblogs and Social Media (ICWSM 2007)http://ebiquity.umbc.edu/blogger/icwsm-2007-blogs-dataset/
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Why existing models are not enough?
Erdos-Renyi random model
Barabasi Albert preferential attachment
web model
Preferential Attachment: The likelihood of linking to a popular website is higher
[1] M. Newman, “The structure and function of complex networks,” 2003
[3] R. Albert, Statistical mechanics of complex networks. PhD thesis, 2001.
[7] J. Leskovec, M. McGlohon, C. Faloutsos, N. Glance, and M. Hurst, “Cascading behavior in large blog graphs”, ICWSM, 2007
[32] X. Shi, B. Tseng, and L. Adamic, “Looking at the blogosphere topology through different lenses” ICWSM, 2007
•Two level network: blog and post level
•Inlinks and outlinks to and from posts
•NEED to model blogger interactions
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Interactions in blogosphere
• Interesting findings from PEW Internet survey [1]- Blog writers are enthusiastic blog readers- Most bloggers post infrequently- Linking in the neighborhood: preferential or random?
(friends blog, blogroll)
• Blogger tend to link to some (how many?) of the posts that they read recently (often preferentially, sometimes random)
• Is popularity (inlinks) proportional to blogger activity (outlinks)? [NO] [2]
[1] A. Lenhart and S. Fox, “Bloggers: A portrait of the internet’s new storytellers.”[2] J. Leskovec, M. McGlohon, C. Faloutsos, N. Glance, and M. Hurst, “Cascading behavior in large blog graphs”, ICWSM 2007
Model parameters
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Model Parameters
1. Probability of random reads (rR)
2. Probability of randomly selecting writer (rW)
3. Probability that new node does not link to the existing network (pD)
4. Growth exponent (g) – how many links should be added every step?
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Proposed Model: Blog view
Should I link to someone? If yes who?
>> Preferentially based on indegree of node
1. Add new blog node
2. Select writer
3. Writers read blog posts, write posts
Writer selection: randomly? OR>> Preferentially based on outdegree?
Should I read - randomly? - preferentially?
I will not link to anyone!
Random writer Random destination
Reciprocal links
Strongly connected components Subset of nodes having directed path from every node to every other node
Weakly connected components
Information flow
Step=1Step=2
michellemalkin
dailykos
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Proposed Model: Post view
Number of links?
Blogger A Blogger B
Post 1
Post 1
Post 2
Post 2
Post 3
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Growth of blog graphs: Densification
Densification [1] has been observed in various real networks including blogosphere
Number of edges grows faster than number of nodes: super linear growth function
[1] ] J. Leskovec, M. McGlohon, C. Faloutsos, N. Glance, and M. Hurst, “Cascading behavior in large blog graphs”, ICWSM 2007
Reciprocity and clustering coefficient increase with growth exponent
Average degree increases with growth (evolution time)
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Properties of simulated blog network
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Properties of simulated post network
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Blogosphere: Blog Inlinks distribution
Blogosphere follows power law distribution for blog inlinks and outlinks, post inlinks and post outlinks, component sizes, posts per blog, size of cascades …
Power law distribution
Slope = -2.07
Very few blog nodes have very high inlinks
Large number of blog nodes have very few inlinks
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Simulation: Blog Inlinks distribution
Similar curves are observed for properties of simulated blog and posts networks
Power law distribution
Slope = -1.72
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Power law distributions for various network sizes
Similar shape of curves for degree distributions as observed by Shi et al [1] in the “real” blogosphere.
[1] X. Shi, B. Tseng, and L. Adamic, “Looking at the blogosphere topology through different lenses,” in ICWSM, 2007
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Hop plotAverage neighborhood size Vs. Hop count
Hop plot shows the reachability of nodes in the network
After N hops, hop plot becomes constant
Comparison of hop plots for ICWSM, WWE and Blogosphere (650K blog nodes, 1.4 million links)
Reachability?
pD = probability that new node remains disconnected
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Simulation: Scatter plot and degree correlations
Correlation Coefficients
ICWSM: 0.056
WWE: 0.02
Simulation: 0.1
Correlation coefficient close to zero means there is NO definite relation between indegree and outdegree of blog nodes
Random writers (rW) helps to model low correlation coefficient
Popular blogs (high inlinks) Popular avid writers
(high inlinks and outlinks)
Avid writers (high outlinks)
BA model
correlation coefficient = 1
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Distribution of SCC in blog and post network (WWE and Simulation)
Community detection, modeling influence uses connected components
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Distribution of WCC in post network (WWE and Simulation)
Power law distribution in WCC for post
network
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Simulation: Posts per blog distribution
Posts per blog also follows a power law distribution [1]
[1] ] J. Leskovec, M. McGlohon, C. Faloutsos, N. Glance, and M. Hurst, “Cascading behavior in large blog graphs”, ICWSM 2007
Power law distribution
Slope = -1.71
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Effect of increase in blogs
Degree distributions almost the same
Reciprocity increases
Average degree increases
Clustering coefficient and reciprocity of the post network is much less compared to the blog network
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Effect of parametersRandom reads (rR), random writers (rW), disconnected nodes (pD)
Increasing rR (random reads), decreases reciprocity because it reduces the likelihood of getting reverse link
Empirically rW = 0.35 (random writers) gives low degree correlation and similar values for other parameters as the blogosphere
Increasing pD reduces the size of largest WCC
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Conclusion
1. Simulation resembles blogosphere in degree distributions, degree correlations, reciprocity, average degree, clustering coefficient, component distribution for blog and post networks.
2. Simulated post network is sparse compared to blog network and posts per blogs follows a power law distribution as observed in blogosphere.
3. Useful tool for analysis of blogosphere, testing new algorithms and extrapolation (how will increase in X affect some Y?)
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Future work
• Can we model buzz and popularity in the post network?
• What is the effect of buzz on the properties of the network?
• In-depth temporal analysis of evolving blog graphs
• Can we enrich the model with topical information?
• How can we model the blogroll?
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Questions?
Thank you!
AcknowledgementsAdvisor, committee members, coauthors, friends at UMBC
DataBlogPulse, ICWSM, WWE