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Location Mining from Online Social Networks
Satyen Abrol Advisors: Dr. Latifur Khan Dr. Bhavani Thuraisingham
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Location Mining in Online Social Networks
What is the city level home location of a user?
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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Why is Location Important?
Privacy and Security Trustworthiness Location Driven Mining for Business Location-Based Social Networking to generate US $21.14 billion by 20151 But only ~14.3% provide it explicitly2 1 According to New Report by Global Industry Analysts, Inc., (GIA) ( 2 According to an experiment performed by us on 1 million users
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Twitter - Basics Location # of Followers # of Following # of Tweets
Maximum 140 Characters
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Why is location so important?
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Privacy and Security Losing locational privacy forever
Users leave field blank, don’t want strangers to know their locations
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Trustworthiness Trustworthiness is important in such cases
To be able to trust/verify the correctness of location mentioned in user profile Corporate companies use social media for better advertising and marketing Iran Elections of 2009 US State Department used Twitter as a source Trustworthiness is important in such cases
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Marketing and Business
Large corporations Walmart, Starbucks, United Airlines use social media Great tool for inexpensive advertising Getting feedback from users
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The Problem Leave the location field blank in their Twitter profiles
Do not provide valid geographic information “Justin Biebers heart”, “NON YA BISNESS!!”, “looking down on u people” Provide incorrect locations which may actually exist in real world “Nothing” in Arizona, “Little Heaven” in Connecticut Provide several locations, difficult to identify the home location “CALi b0Y $TuCC iN V3Ga$” – California boy stuck in Las Vegas, NV (~35%) enter just country, state, county, etc. and no city level locations1 B. Hecht, L. Hong, B. Suh, E. H. Chi, “Tweets from justin biebers heart: the dynamics of the location field in user profiles”, In SIGCHI ’11.
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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Location Prediction in Social Networks
Two Approaches Content Based1,2 Using Social Graph3,4,5 Z. Cheng, J. Caverlee, and K. Lee, “You are where you tweet: A content-based approach to geo-locating twitter users”. In CIKM ’10. B. Hecht, L. Hong, B. Suh, E. H. Chi, “Tweets from justin biebers heart: the dynamics of the location field in user profiles”, In SIGCHI ’11. S. Abrol, L. Khan and B. Thuraisingham,“Tweeque: Spatio-Temporal Analysis of Social Networks for Location Mining Using Graph Partitioning,” The First ASE/IEEE International Conference on Social Informatics, December 14-16, 2012, Washington D.C., USA. S. Abrol., L. Khan and B. Thuraisingham “Tweecalization: Efficient and intelligent location mining in Twitter using semi-supervised learning,” 8th IEEE International Conference on Collaborative Computing, October 14–17, 2012 Pittsburgh, Pennsylvania. S. Abrol., L. Khan, “Agglomerative clustering on fuzzy k-closest friends with variable depth for location mining,” The Second IEEE International Conference on Social Computing (SocialCom2010), Aug 20-22, 2010 Minneapolis, Minnesota.
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Content Based Approach
Inaccurate – Location in Text not Location of User Involves Ambiguity: Paris can mean Paris Hilton Paris, the capital of France Paris, a town in Texas Slow – Uses NLP/ Machine Learning techniques, searches gazetteers
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Using Social Graphs Based on Japanese Proverb - “When the character of a man is not clear to you, look at his friends.” Relationship between geospatial proximity and friendship Uses classical data mining algorithms for more accurate results Faster and can be used for real world applications
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Geospatial Proximity and Friendship
Form 1012 Twitter user pairs and identify geo distance Curve follows power law, curve of form a(x+b)-c with exponent of -0.87
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Graph Construction Vertices (data points) represents users
Edge represents ‘similarity’ between two users Deal with special cases Spammers – follow random people Celebrities – followed by random people Edge weight gets abbreviated
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Defining Edge Weight Consists of two components: Trustworthiness (TW)
Mutual Friends (MF)
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Trustworthiness Fraction of friends which have the same label as the user himself Intuition: A person who has stayed at the same place all his life will have most friends from same location and hence high trustworthiness Location : Seattle/WA/USA A B C D E F G H I J Location : Seattle/WA/USA Location : Seattle/WA/USA Trustworthiness: 0.6 Friend Location:Seattle/WA/USA Location : Seattle/WA/USA Location : Seattle/WA/USA Location : Seattle/WA/USA
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Mutual Friends Chose number common friends for similarity
Better Accuracy Low Time Complexity
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Defining Edge Weight Defined as
Weightij=α×Max{TW(Ui), TW(Uj)} + (1- α) × MFij 0<α<1, typically chosen to be around 0.7
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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Tweethood: Fuzzy k-Closest Friends with Variable Depth
Choose k “closest” friends for the user If location is not found look further for the answer Each node is defined by a vector having locations with their respective probabilities Boost and Aggregate at each step Satyen Abrol, Latifur Khan, “TweetHood: Agglomerative Clustering on Fuzzy k-Closest Friends with Variable Depth for Location Mining”. In Proc. of the Second IEEE International Conference on Social Computing (SocialCom-2010), Minneapolis, USA, August 20-22, 2010
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Agglomerative Clustering
Don’t want to find just any location Want a location or group of locations with some confidence Tradeoff between number of locations, distance between concepts, and total confidence Construct matrix at each step with Objective Function of the above attributes. Choose concepts with maximum values Continue till we cross threshold
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Find the location of John Doe
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Social Network of John Doe
Friend 1 Friend 2 Friend 3 Friend n CB1 CB2 CB3 CBn
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Choose k closest friends of John Doe
Friend k CB1 CB2 CB3 CBk
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LOW ACCURACY Identify Locations Location : NULL
Friend 1 Friend 2 Friend 3 Friend k Location : NULL CB1 LOW ACCURACY Location : Seattle, USA CB2 CB3 Location : NULL CBk Location : NULL
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What if we have depth=2 ? CB1 CB2 CB3 CBk Location : Seattle/WA/USA
G H I J Location : Seattle/WA/USA Location : NULL Location : NULL Location : Dallas/TX/USA Friend 1 Friend 2 Friend 3 Friend k Location : NULL Location : Sydney/AU CB1 Location : Dallas/TX/USA CB2 Location : NULL Location : Richardson/TX/USA CB3 Location : NULL CBk
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Location Vector for John Doe’s friends
Dallas/TX/USA 0.4 Seattle/WA/USA 0.2 Richardson/TX/USA 0.2 Sydney/AU 0.2 Friend 1 Friend 2 Friend 3 Friend k CB1 Dallas/TX/USA 0.33 New Delhi/Delhi/India 0.33 Sunnyvale/CA/USA 0.33 CB2 CB3 Austin/TX/USA 0.50 Minneapolis/MN/USA 0.50 CBk Plano/TX/USA 0.25 Boulder/CO/USA 0.25 Salt Lake City/UT/USA 0.25 London/London/GB 0.25
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Location Vector for John Doe
Dallas/TX/USA Seattle/WA/USA 0.05 Richardson/TX/USA 0.05 Sydney/AU 0.05 New Delhi/Delhi/IN Sunnyvale/CA/USA Austin/TX/USA Minneapolis/MN/USA 0.125 Plano/TX/USA Boulder/CO/USA Salt Lake City/UT/US London/GB
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Agglomerative Clustering
John Doe Dallas/TX/USA Seattle/WA/USA 0.05 Richardson/TX/USA 0.05 Sydney/AU 0.05 New Delhi/Delhi/IN Sunnyvale/CA/USA Austin/TX/USA Minneapolis/MN/USA 0.125 Plano/TX/USA Boulder/CO/USA Salt Lake City/UT/US London/GB
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Agglomerative Clustering
John Doe {Dallas, Plano, Richardson}/TX/USA Seattle/WA/USA 0.05 Sydney/AU 0.05 New Delhi/Delhi/IN Sunnyvale/CA/USA Austin/TX/USA Minneapolis/MN/USA 0.125 Boulder/CO/USA Salt Lake City/UT/US London/GB
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Tweethood: Algorithm
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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Tweecalization: Label Propagation
But the availability of users with location is limited Most of users do not have a location Need a method that can learn from unlabeled data Satyen Abrol, Latifur Khan and Bhavani Thuraisingham, “Tweecalization: Efficient and Intelligent location mining in Twitter using semi- supervised learning,” 8th IEEE International Conference on Collaborative Computing, October 14–17, 2012, Pittsburgh, Pennsylvania
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Tweecalization: Label Propagation
Ideal scenario for semi supervised learning: Only a few friends with locations(labeled data)1 Use both labeled and unlabeled data for training Points which are close to each other are more likely to share a label Y. Bengio, O. Dellalleau, and N. L. Roux, “Label propagation and quadratic criterion,” In O. Chapelle, B. Schlkopf and A. Zien (Eds.), Semi-supervised learning. MIT Press, 2006.
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Label Propagation: An Illustration
“CLAMPED LOCATIONS” Central User Friends with location Friends without location ?
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Tweecalization: Algorithm
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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What About Temporal Analysis?
None of the existing works do temporal analysis What about migration/ geographical mobility?
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Migration/Geographical Mobility
4% to 6% every year, means 12 to 17 million each year United States Census Bureau - Geographical Mobility/Migration Data -
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Migration/Geographical Mobility
Migration as a function of age People aged have a higher probability to move High Migration Rate: College and Jobs Low Migration Rate: Old age, people settle down United States Census Bureau - Geographical Mobility/Migration Data -
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Facebook Users and Mobility
Let us look at the cumulative effect Only 28% to 37% are currently living in their hometown Based on our experiments on 300k Public Facebook Profiles
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Twitter Users and Mobility
Linking Twitter users to migration 33% of all Twitter users are aged years Based on our findings by [1] ABI Research. Online. Available:
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Tweeque: Graph Partitioning
How do we know if “this” is the current location for a user? How do we perform temporal analysis of friendships? Propose a technique that indirectly infers the current location Satyen Abrol, Latifur Khan and Bhavani Thuraisingham,“Tweeque: Spatio-Temporal Analysis of Social Networks for Location Mining Using Graph Partitioning,” The First ASE/IEEE International Conference on Social Informatics, December 14-16, 2012, Washington D.C., USA.
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Observation 1: Social Cliques and Location
Our definition: A social clique is an inclusive group of people that share friendship Apart from friendship, what is the attribute that links members of a clique? Individual Locations All members of a clique were or are at a particular geographical location at a particular instant of time like college, school, a company, etc.
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Observation 2: Migration and Time
As shown previously over course of time, people have tendency to migrate Based on these two observations we hypothesize If we can divide the social graph of a particular user into cliques and check for location based purity of the cliques, we can accurately separate out his current location from previous locations. Migration is our latent time factor
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Friends from high school in Dallas Friends from college in Boston
Tweeque: An example Friend 1 Friend 2 Friend 3 Friend 4 Friend 5 Friend 6 Friend 7 Friend n Friends from high school in Dallas Friends from college in Boston Relatives/Cousins Friends from job in Seattle
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Tweeque: An example All Friends of the User
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Tweeque: An example Social Clique #1 (High School)
Social Clique #2 (College) Social Clique #3 (Current Work) Social Clique #4 (Relatives)
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Tweeque: An Example High School College Relatives Work Dallas/TX/USA
Boston/MA/USA Singapore Seattle/WA/USA Seattle/WA/USA Portland/OR/USA Sydney/Australia Seattle/WA/USA Dallas/TX/USA Austin/TX/USA Dallas/TX/USA Dallas/TX/USA San Diego/CA/USA Boston/MA/USA Dallas/TX/USA Seattle/WA/USA New York/NY/USA Dallas/TX/USA Ontario/Canada Redmond/WA/USA Purity (Dallas) = 0.32 Purity (Boston) = 0.45 Purity (Dallas) = 0.18 Purity (Seattle) = 0.69
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Tweeque: Graph Partitioning
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Tweeque: Graph Partitioning
J. Shi and J. Malik, “Normalized Cuts and Image Segmentation,” IEEE Trans. Pattern Analysis and Machine Intelligence, vol. 22, no. 8, pp , Aug
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Tweeque: Graph Partitioning
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Tweeque: Algorithm
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Tweeque: Purity Voting
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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Experiment Data Randomly choose 1000 Twitter users
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Experiments and Results
75.5% for city level prediction 80.1% for country level prediction We observe that the accuracy saturates after depth 4 Six degrees of separation is the idea that everyone is on average approximately six steps away, by way of introduction, from any other person in the world` For Twitter this distance is found to be 4.67
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Comparison of Different Approaches
Tweethood1 Tweecalization2 Tweeque3 Content Based4 Accuracy (City) 72.1% 75.5% 76.3% 35.6% - 51% Accuracy (Country) 80.1% 84.9% 52.3% Complexity O(n) O(n3) N/A Temporal Analysis No Yes Satyen Abrol, Latifur Khan, “TweetHood: Agglomerative Clustering on Fuzzy k-Closest Friends with Variable Depth for Location Mining”. In Proc. of the Second IEEE International Conference on Social Computing (SocialCom-2010), Minneapolis, USA, August 20-22, 2010 (Nominated for best paper award, Acceptance Rate:13%) Satyen Abrol, Latifur Khan and Bhavani Thuraisingham, “Tweecalization: Efficient and Intelligent location mining in Twitter using semi- supervised learning,” 8th IEEE International Conference on Collaborative Computing, October 14–17, 2012, Pittsburgh, Pennsylvania Satyen Abrol, Latifur Khan and Bhavani Thuraisingham,“Tweeque: Spatio-Temporal Analysis of Social Networks for Location Mining Using Graph Partitioning,” The First ASE/IEEE International Conference on Social Informatics, December 14-16, 2012, Washington D.C., USA. Z. Cheng, J. Caverlee, and K. Lee, “You are where you tweet: A content-based approach to geo-locating twitter users”. In CIKM ’10.
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Outline Introduction and Problem Statement Different Approaches
Social Graph Based: Our Approaches Tweethood: Fuzzy k – Closest Friends with Variable Depth Tweecalization: Label Propagation Tweeque: Graph Partitioning for Spatio-Temporal Analysis Experiments and Results Future Work
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Contributions Developed three graph based location mining algorithms for online social networks Maps location mining problem to k-nearest neighbor, semi supervised and graph partitioning problem Outperform content based approach in time and accuracy Relationship between geospatial proximity and friendship Effect of geographical mobility on current location of users
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Future Work Combining Content and Graph based methods
Score based geo-tagging technique1 Associating keywords with locations to build probabilistic model: “cowboys” Dallas, “casino” Las Vegas Since tweets have timestamps, it leads to more accurate prediction of current location 1 Satyen Abrol, Latifur Khan, Tahseen Al-khateeb, “MapIt: Smarter Searches using Location Driven Knowledge Discovery and Mining”, In Proc. of 1st SIGSPATIAL ACM GIS 2009 International Workshop on Querying and Mining Uncertain Spatio-Temporal Data (QUeST), Nov 2009, Seattle.
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Future Work Improve scalability of current algorithms using cloud computing framework Each of the friends of a user is handled by a separate node in the distributed environment Micro-level location identification Identify specific points of interests (POIs) such as restaurants, place of work, etc from tweets Identify comfort zone for a user Use Foursquare check-in dataset: over 30 million POIs all over the world
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Publications Satyen Abrol, Latifur Khan and Bhavani Thuraisingham,“Tweeque: Spatio-Temporal Analysis of Social Networks for Location Mining Using Graph Partitioning,” The First ASE/IEEE International Conference on Social Informatics, December 14-16, 2012, Washington D.C., USA. Satyen Abrol, Latifur Khan and Bhavani Thuraisingham, “Tweecalization: Efficient and Intelligent location mining in Twitter using semi- supervised learning,” 8th IEEE International Conference on Collaborative Computing, October 14–17, 2012, Pittsburgh, Pennsylvania Satyen Abrol, Latifur Khan, “TweetHood: Agglomerative Clustering on Fuzzy k-Closest Friends with Variable Depth for Location Mining”. In Proc. of the Second IEEE International Conference on Social Computing (SocialCom-2010), Minneapolis, USA, August 20-22, 2010 (Nominated for best paper award, Acceptance Rate:13%)
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Publications Satyen Abrol And Latifur Khan, “TWinner: Understanding News Queries With Geo-Content Using Twitter”. In Proc. of 6th Workshop on Geographic Information Retrieval (GIR'10) At Zurich, Switzerland. Satyen Abrol, Latifur Khan, Tahseen Al-khateeb, “MapIt: Smarter Searches using Location Driven Knowledge Discovery and Mining”, In Proc. of 1st SIGSPATIAL ACM GIS 2009 International Workshop on Querying and Mining Uncertain Spatio-Temporal Data (QUeST), Nov 2009, Seattle. Satyen Abrol, Latifur Khan, Vaibhav Khadilkar, Bhavani M. Thuraisingham, Tyrone Cadenhead, “Design and implementation of SNODSOC: Novel class detection for social network analysis”, ISI 2012:
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Thank You! Questions?
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