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Big Data Infrastructure Week 9: Data Mining (4/4) This work is licensed under a Creative Commons Attribution-Noncommercial-Share Alike 3.0 United States.

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Presentation on theme: "Big Data Infrastructure Week 9: Data Mining (4/4) This work is licensed under a Creative Commons Attribution-Noncommercial-Share Alike 3.0 United States."— Presentation transcript:

1 Big Data Infrastructure Week 9: Data Mining (4/4) This work is licensed under a Creative Commons Attribution-Noncommercial-Share Alike 3.0 United States See http://creativecommons.org/licenses/by-nc-sa/3.0/us/ for details CS 489/698 Big Data Infrastructure (Winter 2016) Jimmy Lin David R. Cheriton School of Computer Science University of Waterloo March 10, 2016 These slides are available at http://lintool.github.io/bigdata-2016w/

2 What’s the Problem? Arrange items into clusters High similarity (low distance) between items in the same cluster Low similarity (high distance) between items in different clusters Cluster labeling is a separate problem

3 Compare/Contrast Finding similar items Focus on individual items Clustering Focus on groups of items Relationship between items in a cluster is of interest

4 Evaluation? Classification Finding similar items Clustering

5 Source: Wikipedia (Star cluster)

6 Clustering Specify distance metric Jaccard, Euclidean, cosine, etc. Compute representation Shingling, tf.idf, etc. Apply clustering algorithm

7 Distances Source: www.flickr.com/photos/thiagoalmeida/250190676/

8 Distance Metrics 1. Non-negativity: 2. Identity: 3. Symmetry: 4. Triangle Inequality

9 Distance: Jaccard Given two sets A, B Jaccard similarity:

10 Distance: Hamming Given two bit vectors Hamming distance: number of elements which differ

11 Distance: Norms Given: Euclidean distance (L 2 -norm) Manhattan distance (L 1 -norm) L r -norm

12 Distance: Cosine Given: Idea: measure distance between the vectors Thus: Advantages over others?

13 Representations

14 Representations: Text Unigrams (i.e., words) Shingles = n-grams At the word level At the character level Feature weights boolean tf.idf BM25 …

15 Representations: Beyond Text For recommender systems: Items as features for users Users as features for items For graphs: Adjacency lists as features for vertices With log data: Behaviors (clicks) as features

16 General Clustering Approaches Hierarchical K-Means Gaussian Mixture Models

17 Hierarchical Agglomerative Clustering Start with each document in its own cluster Until there is only one cluster: Find the two clusters c i and c j, that are most similar Replace c i and c j with a single cluster c i  c j The history of merges forms the hierarchy

18 HAC in Action ABCDEFGHABCDEFGH

19 Cluster Merging Which two clusters do we merge? What’s the similarity between two clusters? Single Link: similarity of two most similar members Complete Link: similarity of two least similar members Group Average: average similarity between members

20 Link Functions Single link: Uses maximum similarity of pairs: Can result in “straggly” (long and thin) clusters due to chaining effect Complete link: Use minimum similarity of pairs: Makes more “tight” spherical clusters

21 MapReduce Implementation What’s the inherent challenge?

22 K-Means Algorithm Let d be the distance between documents Define the centroid of a cluster to be: Select k random instances {s 1, s 2,… s k } as seeds. Until clusters converge: Assign each instance x i to the cluster c j such that d(x i, s j ) is minimal Update the seeds to the centroid of each cluster For each cluster c j, s j =  (c j )

23 Compute centroids   K-Means Clustering Example Pick seeds Reassign clusters   Compute centroids Reassign clusters Converged!

24 Basic MapReduce Implementation (Just a clever way to keep track of denominator)

25 MapReduce Implementation w/ IMC What about Spark?

26 Implementation Notes Standard setup of iterative MapReduce algorithms Driver program sets up MapReduce job Waits for completion Checks for convergence Repeats if necessary Must be able keep cluster centroids in memory With large k, large feature spaces, potentially an issue Memory requirements of centroids grow over time! Variant: k-medoids

27 Clustering w/ Gaussian Mixture Models Model data as a mixture of Gaussians Given data, recover model parameters Source: Wikipedia (Cluster analysis)

28 Gaussian Distributions Univariate Gaussian (i.e., Normal): A random variable with such a distribution we write as: Multivariate Gaussian: A vector-value random variable with such a distribution we write as:

29 Univariate Gaussian Source: Wikipedia (Normal Distribution)

30 Multivariate Gaussians Source: Lecture notes by Chuong B. Do (IIT Delhi)

31 Gaussian Mixture Models Model parameters Number of components: “Mixing” weight vector: For each Gaussian, mean and covariance matrix: Varying constraints on co-variance matrices Spherical vs. diagonal vs. full Tied vs. untied The generative story? (yes, that’s a technical term)

32 Learning for Simple Univariate Case Problem setup: Given number of components: Given points: Learn parameters: Model selection criterion: maximize likelihood of data Introduce indicator variables: Likelihood of the data:

33 EM to the Rescue! We’re faced with this: It’d be a lot easier if we knew the z’s! Expectation Maximization Guess the model parameters E-step: Compute posterior distribution over latent (hidden) variables given the model parameters M-step: Update model parameters using posterior distribution computed in the E-step Iterate until convergence

34

35 EM for Univariate GMMs Initialize: Iterate: E-step: compute expectation of z variables M-step: compute new model parameters

36 MapReduce Implementation z 1,1 z 2,1 z 3,1 z N,1 z 1,2 z 2,2 z 3,3 z N,2 z 1,K z 2,K z 3,K z N,K … … x1x1 x2x2 x3x3 xNxN Map Reduce What about Spark?

37 K-Means vs. GMMs Map Reduce K-MeansGMM Compute distance of points to centroids Recompute new centroids E-step: compute expectation of z indicator variables M-step: update values of model parameters

38 Source: Wikipedia (k-means clustering)

39 Source: Wikipedia (Japanese rock garden) Questions?

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