Advanced Search Techniques for Large Scale Data Analytics Pavel Zezula and Jan Sedmidubsky Masaryk University http://disa.fi.muni.cz ¡Given a cloud of data points we want to understand its structure Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 2 http://www.cs.toronto.edu/~laurens/drtoronto/Dimensionality_Reduction_@_Toronto_files/shapeimage_2. png 3 ¡Given a set of points, with a notion of distance between points, group the points into some number of clusters, so that §Members of a cluster are close/similar to each other §Members of different clusters are dissimilar ¡Usually: §Points are in a high-dimensional space §Similarity is defined using a distance measure §Euclidean, Cosine, Jaccard, edit distance, … Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 4 x x x x x x x x x x x x x x x x xx x x x x x x x x x x x x x x x x x x x x x x x Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) x x x x x x x x x x x x x x x x xx x x x x x x x x x x x x x x x x x x x x x Outlier Cluster Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 5 http://tagc.univ-mrs.fr/tagc/images/dputhier/tb2.jpg 6 ¡Clustering in two dimensions looks easy ¡Clustering small amounts of data looks easy ¡And in most cases, looks are not deceiving ¡ ¡Many applications involve not 2, but 10 or 10,000 dimensions ¡High-dimensional spaces look different: Almost all pairs of points are at about the same distance Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 7 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 8 9 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) ¡As with CDs we have a choice when we think of documents as sets of words or shingles: §Sets as vectors: Measure similarity by the cosine distance §Sets as sets: Measure similarity by the Jaccard distance §Sets as points: Measure similarity by Euclidean distance Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 10 11 http://www.mathworks.com/help/toolbox/stats/dendrogram.gif http://www.ima.umn.edu/~iwen/REU/2Ddata.jpg Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) ¡Key operation: Repeatedly combine two nearest clusters § ¡Three important questions: §1) How do you represent a cluster of more than one point? §2) How do you determine the “nearness” of clusters? §3) When to stop combining clusters? Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 12 http://www.mathworks.com/help/toolbox/stats/dendrogram.gif ¡Key operation: Repeatedly combine two nearest clusters ¡(1) How to represent a cluster of many points? §Key problem: As you merge clusters, how do you represent the “location” of each cluster, to tell which pair of clusters is closest? ¡Euclidean case: each cluster has a centroid = average of its (data)points ¡(2) How to determine “nearness” of clusters? §Measure cluster distances by distances of centroids Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 13 14 (5,3) o (1,2) o o (2,1) o (4,1) o (0,0) o (5,0) x (1.5,1.5) x (4.5,0.5) x (1,1) x (4.7,1.3) Data: o … data point x … centroid Dendrogram Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 15 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) ¡(1) How to represent a cluster of many points? clustroid = point “closest” to other points ¡Possible meanings of “closest”: §Smallest maximum distance to other points §Smallest average distance to other points §Smallest sum of squares of distances to other points §For distance metric d clustroid c of cluster C is: § Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 16 Centroid is the avg. of all (data)points in the cluster. This means centroid is an “artificial” point. Clustroid is an existing (data)point that is “closest” to all other points in the cluster. X Cluster on 3 datapoints Centroid Clustroid Datapoint ¡(2) How do you determine the “nearness” of clusters? §Approach 2: Intercluster distance = minimum of the distances between any two points, one from each cluster §Approach 3: Pick a notion of “cohesion” of clusters, e.g., maximum distance from the clustroid §Merge clusters whose union is most cohesive 17 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) ¡Approach 3.1: Use the diameter of the merged cluster = maximum distance between points in the cluster ¡Approach 3.2: Use the average distance between points in the cluster ¡Approach 3.3: Use a density-based approach §Take the diameter or avg. distance, e.g., and divide by the number of points in the cluster Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 18 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 19 21 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 22 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 23 x x x x x x x x x … data point … centroid x x x Clusters after round 1 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 24 x x x x x x x x x … data point … centroid x x x Clusters after round 2 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 25 x x x x x x x x x … data point … centroid x x x Clusters at the end ¡How to select k? ¡Try different k, looking at the change in the average distance to centroid as k increases ¡Average falls rapidly until right k, then changes little 26 k Average distance to centroid Best value of k Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 27 x x x x x x x x x x x x x x x x xx x x x x x x x x x x x x x x x x x x x x x x x Too few; many long distances to centroid. Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 28 x x x x x x x x x x x x x x x x xx x x x x x x x x x x x x x x x x x x x x x x x Just right; distances rather short. Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 29 x x x x x x x x x x x x x x x x xx x x x x x x x x x x x x x x x x x x x x x x x Too many; little improvement in average distance. Extension of k-means to large data 31 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) http://hyperphysics.phy-astr.gsu.edu/hbase/math/immath/gauds.gif ¡Points are read from disk one main-memory-full at a time ¡Most points from previous memory loads are summarized by simple statistics ¡To begin, from the initial load we select the initial k centroids by some sensible approach: §Take k random points §Take a small random sample and cluster optimally §Take a sample; pick a random point, and then k–1 more points, each as far from the previously selected points as possible 32 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) ¡3 sets of points which we keep track of: ¡Discard set (DS): §Points close enough to a centroid to be summarized ¡Compression set (CS): §Groups of points that are close together but not close to any existing centroid §These points are summarized, but not assigned to a cluster ¡Retained set (RS): §Isolated points waiting to be assigned to a compression set Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 33 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 34 A cluster. Its points are in the DS. The centroid Compressed sets. Their points are in the CS. Points in the RS Discard set (DS): Close enough to a centroid to be summarized Compression set (CS): Summarized, but not assigned to a cluster Retained set (RS): Isolated points ¡For each cluster, the discard set (DS) is summarized by: ¡The number of points, N ¡The vector SUM, whose ith component is the sum of the coordinates of the points in the ith dimension ¡The vector SUMSQ: ith component = sum of squares of coordinates in ith dimension Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 35 A cluster. All its points are in the DS. The centroid ¡2d + 1 values represent any size cluster §d = number of dimensions ¡Average in each dimension (the centroid) can be calculated as SUMi / N §SUMi = ith component of SUM ¡Variance of a cluster’s discard set in dimension i is: (SUMSQi / N) – (SUMi / N)2 §And standard deviation is the square root of that ¡Next step: Actual clustering 36 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) Note: Dropping the “axis-aligned” clusters assumption would require storing full covariance matrix to summarize the cluster. So, instead of SUMSQ being a d-dim vector, it would be a d x d matrix, which is too big! ¡Processing the “Memory-Load” of points (1): ¡1) Find those points that are “sufficiently close” to a cluster centroid and add those points to that cluster and the DS §These points are so close to the centroid that they can be summarized and then discarded ¡2) Use any main-memory clustering algorithm to cluster the remaining points and the old RS §Clusters go to the CS; outlying points to the RS Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 37 Discard set (DS): Close enough to a centroid to be summarized. Compression set (CS): Summarized, but not assigned to a cluster Retained set (RS): Isolated points Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 38 Discard set (DS): Close enough to a centroid to be summarized. Compression set (CS): Summarized, but not assigned to a cluster Retained set (RS): Isolated points 39 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 40 σi … standard deviation of points in the cluster in the ith dimension ¡Q2) Should 2 CS subclusters be combined? ¡Compute the variance of the combined subcluster §N, SUM, and SUMSQ allow us to make that calculation quickly ¡Combine if the combined variance is below some threshold Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 41 Extension of k-means to clusters of arbitrary shapes 43 http://www.ima.umn.edu/~iwen/REU/2Ddata.jpg Vs. Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) http://www.ml.uni-saarland.de/code/pSpectralClustering/images/eigenvector11b.png 44 e e e e e e e e e e e h h h h h h h h h h h h h salary age Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) ¡2 Pass algorithm. Pass 1: ¡0) Pick a random sample of points that fit in main memory ¡1) Initial clusters: §Cluster these points hierarchically – group nearest points/clusters ¡2) Pick representative points: §For each cluster, pick a sample of points, as dispersed as possible §From the sample, pick representatives by moving them (say) 20% toward the centroid of the cluster Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 45 46 e e e e e e e e e e e h h h h h h h h h h h h h salary age Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 47 e e e e e e e e e e e h h h h h h h h h h h h h salary age Pick (say) 4 remote points for each cluster. Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 48 e e e e e e e e e e e h h h h h h h h h h h h h salary age Move points (say) 20% toward the centroid. Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 49 Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) p ¡Clustering: Given a set of points, with a notion of distance between points, group the points into some number of clusters ¡Algorithms: §Agglomerative hierarchical clustering: §Centroid and clustroid §k-means: §Initialization, picking k §BFR §CURE Pavel Zezula, Jan Sedmidubsky. Advanced Search Techniques for Large Scale Data Analytics (PA212) 50