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Semi-Supervised Classification of Network Data Using Very Few Labels

Semi-Supervised Classification of Network Data Using Very Few Labels. Frank Lin and William W. Cohen School of Computer Science, Carnegie Mellon University ASONAM 2010 2010-08-11, Odense, Denmark. Overview. Preview MultiRankWalk Random Walk with Restart RWR for Classification

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Semi-Supervised Classification of Network Data Using Very Few Labels

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  1. Semi-Supervised Classification of Network Data Using Very Few Labels Frank Lin and William W. Cohen School of Computer Science, Carnegie Mellon University ASONAM 2010 2010-08-11, Odense, Denmark

  2. Overview • Preview • MultiRankWalk • Random Walk with Restart • RWR for Classification • Seed Preference • Experiments • Results • The Question

  3. Preview • Classification labels are expensive to obtain • Semi-supervised learning (SSL) learns from labeled and unlabeled data for classification

  4. Preview [Adamic & Glance 2005]

  5. Preview • When it comes to network data, what is a general, simple, and effective method that requires very few labels? • One that researchers could use as a strong baseline when developing more complex and domain-specific methods? Our Answer: MultiRankWalk (MRW) & Label high PageRank nodes first (authoritative seeding)

  6. Preview • MRW (red) vs. a popular method (blue) Only 1 training label per class! accuracy # of training labels

  7. Preview • The popular method using authoritative seeding (red & green) vs. random seeding (blue) label “authoritative seeds” first Same blue line as before

  8. Overview • Preview • MultiRankWalk • Random Walk with Restart • RWR for Classification • Seed Preference • Experiments • Results • The Question

  9. Random Walk with Restart • Imagine a network, and starting at a specific node, you follow the edges randomly. • But (perhaps you’re afraid of wondering too far) with some probability, you “jump” back to the starting node (restart!). If you record the number of times you land on each node, what would that distribution look like?

  10. Random Walk with Restart What if we start at a different node? Start node

  11. Random Walk with Restart • The walk distribution r satisfies a simple equation: Start node(s) Transition matrix of the network Equivalent to the well-known PageRank ranking if all nodes are start nodes! (u is uniform) Restart probability “Keep-going” probability (damping factor)

  12. Random Walk with Restart • Random walk with restart (RWR) can be solved simply and efficiently with an iterative procedure:

  13. Overview • Preview • MultiRankWalk • Random Walk with Restart • RWR for Classification • Seed Preference • Experiments • Results • The Question

  14. RWR for Classification • Simple idea: use RWR for classification RWR with start nodes being labeled points in class A RWR with start nodes being labeled points in class B Nodes frequented more by RWR(A) belongs to class A, otherwise they belong to B

  15. RWR for Classification We refer to this method as MultiRankWalk: it classifies data with multiple rankings using random walks

  16. Overview • Preview • MultiRankWalk • Random Walk with Restart • RWR for Classification • Seed Preference • Experiments • Results • The Question

  17. Seed Preference • Obtaining labels for data points is expensive • We want to minimize cost for obtaining labels • Observations: • Some labels inherently more useful than others • Some labels easier to obtain than others Question: “Authoritative” or “popular” nodes in a network are typically easier to obtain labels for. But are these labels also more useful than others?

  18. Seed Preference • Consider the task of giving a human expert (or posting jobs on Amazon Mechanical Turk) a list of data points to label • The list (seeds) can be generated uniformly at random, or we can have a seed preference, according to simple properties of the unlabeled data • We consider 3 preferences: • Random • Link Count • PageRank Nodes with highest counts make the list Nodes with highest scores make the list

  19. Overview • Preview • MultiRankWalk • Random Walk with Restart • RWR for Classification • Seed Preference • Experiments • Results • The Question

  20. Experiments • Test effectiveness of MRW and compare seed preferences on five real network datasets: Political Blogs (Liberal vs. Conservative) Citation Networks (7 and 6 academic fields, respectively)

  21. Experiments • We compare MRW against a currently very popular network SSL method – wvRN You may know wvRN as the harmonic functions method, adsorption, random walk with sink nodes, … “weighted-voted relational network classifier” Recommended as a strong network SSL baseline in (Macskassy & Provost 2007)

  22. Experiments • To simulate a human expert labeling data, we use the “ranked-at-least-n-per-class” method Political blog example with n=2: conservative liberal conservative conservative liberal blogsforbush.com dailykos.com moorewatch.com right-thinking.com talkingpointsmemo.com instapundit.com michellemalkin.com atrios.blogspot.com littlegreenfootballs.com washingtonmonthly.com powerlineblog.com drudgereport.com We have at least 2 labels per class. Stop.

  23. Overview • Preview • MultiRankWalk • Random Walk with Restart • RWR for Classification • Seed Preference • Experiments • Results • The Question

  24. Averaged over 20 runs Results • MRW vs. wvRN with random seed preference MRW does extremely well with just one randomly selected label per class! MRW drastically better with a small number of seed labels; performance not significantly different with larger numbers of seeds

  25. Results • wvRN with different seed preferences PageRank slightly better than LinkCount, but in general not significantly so LinkCount or PageRank much better than Random with smaller number of seed labels

  26. Results • Does MRW benefit from seed preference? A rare instance where authoritative seeds hurt performance, but not statistically significant Yes, on certain datasets with small number of seed labels; note the already very high F1 on most datasets

  27. Results • How much better is MRW using authoritative seed preference? y-axis: MRW F1 score minus wvRN F1 x-axis: number of seed labels per class The gap between MRW and wvRN narrows with authoritative seeds, but they are still prominent on some datasets with small number of seed labels

  28. Results • Summary • MRW much better than wvRN with small number of seed labels • MRW more robust to varying quality of seed labels than wvRN • Authoritative seed preference boosts algorithm effectiveness with small number of seed labels We recommend MRW and authoritative seed preference as a strong baseline for semi-supervised classification on network data

  29. Overview • Preview • MultiRankWalk • Random Walk with Restart • RWR for Classification • Seed Preference • Experiments • Results • The Question

  30. The Question • What really makes MRW and wvRN different? • Network-based SSL often boil down to label propagation. • MRW and wvRN represent two general propagation methods – note that they are call by many names: Great…but we still don’t know why the differences in their behavior on these network datasets!

  31. The Question • It’s difficult to answer exactly why MRW does better with a smaller number of seeds. • But we can gather probable factors from their propagation models:

  32. 1. Centrality-sensitive: seeds have different scores and not necessarily the highest The Question Seed labels underlined • An example from a political blog dataset – MRW vs. wvRN scores for how much a blog is politically conservative: 0.020 firstdownpolitics.com 0.019 neoconservatives.blogspot.com 0.017 jmbzine.com 0.017 strangedoctrines.typepad.com 0.013 millers_time.typepad.com 0.011 decision08.blogspot.com 0.010 gopandcollege.blogspot.com 0.010 charlineandjamie.com 0.008 marksteyn.com 0.007 blackmanforbush.blogspot.com 0.007 reggiescorner.blogspot.com 0.007 fearfulsymmetry.blogspot.com 0.006 quibbles-n-bits.com 0.006 undercaffeinated.com 0.005 samizdata.net 0.005 pennywit.com 0.005 pajamahadin.com 0.005 mixtersmix.blogspot.com 0.005 stillfighting.blogspot.com 0.005 shakespearessister.blogspot.com 0.005 jadbury.com 0.005 thefulcrum.blogspot.com 0.005 watchandwait.blogspot.com 0.005 gindy.blogspot.com 0.005 cecile.squarespace.com 0.005 usliberals.about.com 0.005 twentyfirstcenturyrepublican.blogspot.com 1.000 neoconservatives.blogspot.com 1.000 strangedoctrines.typepad.com 1.000 jmbzine.com 0.593 presidentboxer.blogspot.com 0.585 rooksrant.com 0.568 purplestates.blogspot.com 0.553 ikilledcheguevara.blogspot.com 0.540 restoreamerica.blogspot.com 0.539 billrice.org 0.529 kalblog.com 0.517 right-thinking.com 0.517 tom-hanna.org 0.514 crankylittleblog.blogspot.com 0.510 hasidicgentile.org 0.509 stealthebandwagon.blogspot.com 0.509 carpetblogger.com 0.497 politicalvicesquad.blogspot.com 0.496 nerepublican.blogspot.com 0.494 centinel.blogspot.com 0.494 scrawlville.com 0.493 allspinzone.blogspot.com 0.492 littlegreenfootballs.com 0.492 wehavesomeplanes.blogspot.com 0.491 rittenhouse.blogspot.com 0.490 secureliberty.org 0.488 decision08.blogspot.com 0.488 larsonreport.com 2. Exponential drop-off: much less sure about nodes further away from seeds We still don’t completely understand it yet. 3. Classes propagate independently: charlineandjamie.com is both very likely a conservative and a liberal blog (good or bad?)

  33. Questions?

  34. Random walk without restart, heuristic stopping Related Work RWR ranking as features to SVM Similar formulation, different view • MRW is very much related to • “Local and global consistency” (Zhou et al. 2004) • “Web content categorization using link information” (Gyongyi et al. 2006) • “Graph-based semi-supervised learning as a generative model” (He et al. 2007) • Seed preference is related to the field of active learning • Active learning chooses which data point to label next based on previous labels; the labeling is interactive • Seed preference is a batch labeling method Authoritative seed preference a good base line for active learning on network data!

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