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Chapter 3: Data Mining and Data Visualization Modern Data Warehousing, Mining, and Visualization: Core Concepts by George M. Marakas BCIS 4660 Spring 2012 © 2003, Prentice-Hall 1 3-1: A Picture is Worth a Thousand Words • Data mining is the set of activities used to find new, hidden, or unexpected patterns in data. • These techniques are often called knowledge data discovery (KDD), and include statistical analysis, neural or fuzzy logic, intelligent agents or data visualization. • The KDD techniques not only discover useful patterns in the data, but also can be used to develop predictive models. © 2003, Prentice-Hall 2 Verification Versus Discovery • In the past, decision support activities were primarily based on the concept of verification. • This required a great deal of prior knowledge on the decision-maker’s part in order to verify a suspected or known relationship. • With the advance of technology, the concept of verification began to turn into discovery—a.k.a, data mining. © 2003, Prentice-Hall 3 Data Mining’s Growth in Popularity • One reason is that we keep getting more and more data all the time and need tools to understand it. • We also are aware that the human brain has limits processing multidimensional data (RULE of 7). • A third reason is that machine learning techniques are becoming more affordable and more refined at the same time. © 2003, Prentice-Hall 4 Making Accurate Predictions with Data Mining • Although the literature contains statements such as “data mining will allow us to predict who will buy a particular product,” that is against human nature. • In situations where data mining is used to predict response to a marketing campaign, only about 5% of the people selected as “likely respondents” actually do respond. • Even Exit Polls – post-behavior predictions, can be misleading! – E.g., 2004 Presidential election © 2003, Prentice-Hall 5 Making Accurate Predictions with Data Mining (cont.) • Although the accuracy of predicting individual behavior is not so good, it is better than it seems, since direct marketing (mailers, email, phone calls) efforts often have “hit rates” of only about 1% without data mining. • Therefore a 5X increase in successes is quite good! © 2003, Prentice-Hall 6 3-2: Online Analytical Processing (OLAP) Codd (co-founder of relational databases with Date) developed a set of 12 rules for the development of multidimensional databases (Recall Chap. 9 of Pratt): 1. 2. 3. 4. 5. Multidimensional view Transparent to user Accessible Consistent reporting Client-server architecture 6. Generic dimensionality 7. Dynamic sparse matrix handling 8. Multiuser support 9. Cross-dimensional ops 10. Intuitive manipulation 11. Flexible reporting 12. Unlimited dimension and aggregation © 2003, Prentice-Hall 7 OLAP as Implemented • Codd introduced the term OLAP in 1993 • To date, it does not appear that any implementation exists that satisfies all 12 multidimensionality rules. • Some people argue it might not even be possible to attain all of them. • More recently, the term OLAP has come to represent the broad category of software technology that enables multidimensional analysis of enterprise data. © 2003, Prentice-Hall 8 Multidimensional OLAP (MOLAP) • Data can be viewed across several dimensions. Here sales are arrayed by region and product. • A fourth dimension could be added by using several graphs -perhaps at different points of time. • Most analyses have many more dimensions than this. MOLAP handles data as an ndimensional hypercube. • Data slices cut across dimensions (hold one dimension constant) 0.7 0.6 Sales 0.5 0.4 4 3 0.3 © 2003, Prentice-Hall 2 1 Region Product 1 2 3 9 Relational OLAP (ROLAP) • A large relational database server replaces the multidimensional one. • The database contains both detailed and summarized data, allowing “drill down” techniques to be applied. • SQL interfaces allow vendors to build tools, both portable and scalable. • This does require databases with many relational tables (typically 100s+) which may lead to substantial processor overhead on complex joins. © 2003, Prentice-Hall 10 A Typical Relational Schema (ERD) © 2003, Prentice-Hall 11 3-3: Techniques Used to Mine the Data • Paralleling the popularity of data mining itself, the development of new techniques is exploding as well. • Many innovations are vendor-specific (e.g., SAS EM, Cognos), which sometimes does little to advance the state of the art. • Regardless, data-mining techniques tend to fall into four major categories: 1. classification 2. association 3. sequencing 4. clustering © 2003, Prentice-Hall 12 Classification methods • The goal is to discover rules that define whether an item belongs to a particular subset or class of data. • For example, if we are trying to determine which households will respond to a direct mail campaign, we will want rules that separate the “probables” from the “not probables”. • These IF-THEN rules often are portrayed in a tree-like structure or diagram. © 2003, Prentice-Hall 13 Association Methods • These techniques search all transactions from a system for patterns of occurrence. • A common method is market basket analysis (a.k.a, affinity analysis, association analysis), in which the set of products purchased by thousands of consumers are examined. • Results are then portrayed as percentages; for example, “30% of the people that buy steaks also buy charcoal”. © 2003, Prentice-Hall 14 Sequencing Methods • These methods are applied to time series data in an attempt to find hidden trends. • If found, these can be useful predictors of future events (e.g., leading indicators). • For example, customer groups that tend to purchase products tied-in with hit movies would be targeted with promotional campaigns timed to release dates. © 2003, Prentice-Hall 15 Clustering Techniques • Clustering techniques attempt to create partitions in the data according to some distance metric. • The clusters formed are data grouped together simply by their similarity to their neighbors (factor and discriminate analysis). • By examining the characteristics of each cluster, it may be possible to establish rules for classification. © 2003, Prentice-Hall 16 Data Mining Technologies • Statistics – the most mature data mining technologies, but are often not applicable because they need clean data. In addition, many statistical procedures assume linear relationships, which limits their use [Regression, correlation, ANOVA, etc.] • Neural networks, genetic algorithms, fuzzy logic – these technologies are able to work with complicated and imprecise data. Their broad applicability has made them popular in the field. © 2003, Prentice-Hall 17 Data Mining Technologies (cont.) • Decision trees – these technologies are conceptually simple and have gained in popularity as better tree growing software was introduced. Because of the way they are used, they are perhaps better called “classification” trees. © 2003, Prentice-Hall 18 The Knowledge Discovery [KD] Search Process Table 3-2 contains a more detailed outline of the process, but the major steps are: 1. Define the business problem and obtain the data to study it. 2. Use data mining software to model the problem. 3. Mine the data to search for patterns of interest. 4. Review the mining results and refine them by respecifying the model. 5. Once validated, make the model available (publish) to other users of the DW. © 2003, Prentice-Hall 19 Creating a (task-relevant) Data-Mining Model Although syntax differs from vendor to vendor, building a model on top of a database is much like creating a table: CREATE MODEL mail_list (Income character input, Age integer input, Respond character input) To populate it with data, use an SQL INSERT: INSERT INTO mail_list SELECT income, age, respond FROM client_list WHERE region = ‘Southeast” © 2003, Prentice-Hall 20 Creating a Data-Mining Model (cont.) The process automatically created additional views of the model (mail_list_UNDERSTAND and mail_list_PREDICT). These can be examined (MS OLAP pseudo-code): SELECT * FROM mail_list_UNDERSTAND WHERE input_column_name = “income” and input_column_value = “high” and output_column_name = “respond” and output_column_value = “yes” Once these are created, they are treated as tables in the database so they can be viewed and joined by other users. © 2003, Prentice-Hall 21 New Applications for Data Mining As the technology matures, new applications emerge, especially in two new categories, text mining (AskSam) and web mining. Some text mining examples are: – Distilling the meaning (abstract) of a text – Accurate summarization of a text – Explication of the text theme structure – Clustering of texts © 2003, Prentice-Hall 22 Web mining • Web mining is a special case of text mining where the mining occurs over a website (e.g., Amazon.com). • It enhances the website with intelligent behavior, such as suggesting related links or recommending new products. • It allows you to unobtrusively learn the interests of the visitors and modify their user profiles in real time. • They also allow you to match resources to the interests of the visitor. © 2003, Prentice-Hall 23 3-4: Market Basket Analysis: The King of Algorithms • This is the most widely used and, in many ways, most successful data mining algorithm. • Also, known as “Affinity” or “Association” Analysis • It essentially determines what products people purchase together. • Stores can use this information to place these products in the same area. • Direct marketers can use this information to determine which new products to offer to their current customers. • Inventory policies can be improved if reorder points reflect the demand for the complementary products. © 2003, Prentice-Hall 24 Association Rules for Market Basket Analysis Rules are written in the form “left-hand side implies righthand side” and an example is: Yellow Peppers IMPLIES Red Peppers, Bananas, Bakery To make effective use of a rule, three numeric measures about that rule must be considered: (1) support (2) confidence and (3) lift © 2003, Prentice-Hall 25 Measures of Predictive Ability Yellow Peppers IMPLIES [Red Peppers, Bananas, Bakery] 1. Support refers to the percentage of baskets where the rule was true (both left and right side products were present in the basket). Intersection of both sides present. 2. Confidence measures what percentage of baskets that contained the left-hand product also contained the right. e.g., If basket contains Peppers What % contained Bananas Smaller universe, so numbers will be higher 3. Lift measures how much more frequently the left-hand item is found with the right than without the right. Ratio: “Confidence” divided by % of baskets with Peppers that do NOT contain bananas. If 50% of time peppers are found with bananas and 50% not found with bananas, the lift is 1.0 © 2003, Prentice-Hall 26 An Example Rule: Lift Support Confidence Green Peppers IMPLIES Bananas 1.37 3.77 85.96 Red Peppers IMPLIES Bananas 1.43 8.58 89.47 Yellow Peppers IMPLIES Bananas 1.17 22.12 73.09 • The confidence suggests people buying any kind of pepper also buy bananas. • Green peppers sell in about the same quantities as red or yellow, but are not as predictive. © 2003, Prentice-Hall 27 Market Basket Analysis Methodology • We first need a list of transactions and what was purchased. This is pretty easily obtained these days from scanning cash registers. • Next, we choose a list of products to analyze, and tabulate how many times each was purchased with the others. • The diagonals of the table shows how often a product is purchased in any combination, and the off-diagonals show which combinations were bought. © 2003, Prentice-Hall 28 A Convenience Store Example (5 transactions) Consider the following simple example about five transactions at a convenience store: Transaction 1: Transaction 2: Transaction 3: Transaction 4: Transaction 5: Frozen pizza, cola, milk Milk, potato chips Cola, frozen pizza Milk, pretzels Cola, pretzels These need to be cross tabulated and displayed in a table. © 2003, Prentice-Hall 29 A Convenience Store Example (5 transactions; Cross tabulated) Product Bought Pizza also Pizza Milk Cola Chips Pretzels 2 1 2 0 0 Milk also 1 3 Cola also 2 1 1 1 1 3 0 1 Chips also 0 1 0 1 0 Pretzels also 0 1 1 0 2 • Pizza and Cola sell together more often than any other combo; a cross-marketing opportunity? • Milk sells well with everything – people probably come here specifically to buy it. © 2003, Prentice-Hall 30 Using the Results • The tabulations can immediately be translated into association rules and the numerical measures computed. • Comparing this week’s table to last week’s table can immediately show the effect of this week’s promotional activities. • Some rules are going to be trivial (hot dogs and buns sell together) or inexplicable (toilet rings sell only when a new hardware store is opened). © 2003, Prentice-Hall 31 Limitations to Market Basket Analysis • A large number of real transactions are needed to do an effective basket analysis, but the data’s accuracy is compromised if all the products do not occur with similar frequency. Statistical insignificance results with “empty” cells. • The analysis can sometimes capture results that were due to the success of previous marketing campaigns (and not natural tendencies of customers). © 2003, Prentice-Hall 32 Performing Analysis with Virtual Items • The sales data can be augmented with the addition of virtual items. For example, we could record that the customer was new to us, or had children. • The transaction record might look like: Item 1: Sweater Item 2: Jacket Item 3: New • This might allow us to see what patterns new customers have versus old customers. © 2003, Prentice-Hall 33 Taxonomies • The presence of items not purchased very frequently is an obstacle to a good market basket analysis [missing data]. • One way to deal with this is to eliminate products that occur with a frequency less than some threshold. • A better idea would be to try to form groups of products that fall below the threshold. Four flavors of popsicle occur 9% of the time all together, but no more than 3% individually. © 2003, Prentice-Hall 34 Multidimensional Market Basket Analysis • Rules can involve more than two items, for example Plant and Clay Pot IMPLIES Soil. • These rules are built iteratively. First, pairs are found, then relevant sets of three or four. • These are then pruned by removing those that occur infrequently. • In an environment like a grocery store, where customers commonly buy over 100 items, rules could involve as many as 10 items. © 2003, Prentice-Hall 35 3-5: Current Limitations and Challenges to Data Mining Despite the potential power and value, data mining is still a new field. Some things that that thus far have limited advancement are: – Identification of missing information – not all knowledge gets stored in a database – Data noise and missing values – future systems need better ways to handle this – Large databases and high dimensionality – future applications need ways to partition data into more manageable chunks © 2003, Prentice-Hall 36 3-6: Data Visualization: “Seeing” the Data © 2003, Prentice-Hall 37 Visual Presentation • For any kind of high dimensional data set, displaying predictive relationships is a challenge. • The picture on the previous slide uses 3-D graphics to portray the weather balloon data numbers in text Table 11-4. We learn very little from just examining the numbers . • Shading is used to represent relative degrees of thunderstorm activity, with the darkest regions the heaviest activity. © 2003, Prentice-Hall 38 A Bit of History • An early effort used sequences of two-dimensional graphs to add depth. • Current virtual reality programs allow the user to step through a data set. Try going to a realtor’s website and taking a tour of a house up for sale. http://www.microsoft.com/solutions/bi/overview/visualizatio n.asp © 2003, Prentice-Hall 39 Data Visualization Data visualization refers to presentation of data by technologies such as digital images, geographical information systems, graphical user interfaces, multidimensional tables and graphs, virtual reality, threedimensional presentations, videos and animation. • Multidimensionality Visualization: Modern data and information may have several dimensions. – Dimensions: • • • • • • • • Products Salespeople Market segments Business units Geographical locations Distribution channels Countries Industries © 2003, Prentice-Hall 40 Data Visualization Continued Multidimensionality Visualization: • Measures: • Money • Sales volume • Head count • Inventory profit • Actual versus forecasted results. • Time: • Daily • Weekly • Monthly • Quarterly • Yearly. © 2003, Prentice-Hall 41 Data Visualization Continued © 2003, Prentice-Hall 42 Data Visualization Continued • A geographical information system (GIS) is a computer-based system for capturing, storing, checking, integrating, manipulating, and displaying data using digitized maps. Every record or digital object has an identified geographical location. It employs spatially oriented databases. • Visual interactive modeling (VIM) uses computer graphic displays to represent the impact of different management or operational decisions on objectives such as profit or market share. • Virtual reality (VR) is interactive, computer-generated, three-dimensional graphics delivered to the user. These artificial sensory cues cause the user to “believe” that what they are doing is real. © 2003, Prentice-Hall 43 Human Visual Perception and Data Visualization • • Data visualization is so powerful because the human visual cortex converts objects into information so quickly. The next three slides show: (1) usage of global private networks, (2) flow through natural gas pipelines, and (3) a risk analysis report that permits the user to draw an interactive yield curve. • All three use height or shading to add additional dimensions to the figure. © 2003, Prentice-Hall 45 Global Private Network Activity High Activity Low Activity © 2003, Prentice-Hall 46 Natural Gas Pipeline Analysis Note: Height shows total flow through compressor stations. © 2003, Prentice-Hall 47 An “Enlivened” Risk Analysis Report © 2003, Prentice-Hall 48 Geographical Information Systems (GIS) A GIS is a special purpose database that contains a spatial coordinate system. A comprehensive GIS requires: 1. 2. 3. 4. Data input from maps, aerial photos, etc. Data storage, retrieval and query Data transformation and modeling Data reporting (maps, reports and plans) © 2003, Prentice-Hall 49 The Power of Visualization: Driving directions 1. Start out going Southwest on ELLSWORTH AVE Towards BROADWAY by turning right. 2: Turn RIGHT onto BROADWAY. 3. Turn RIGHT onto QUINCY ST. 4. Turn LEFT onto CAMBRIDGE ST. 5. Turn SLIGHT RIGHT onto MASSACHUSETTS AVE. 6. Turn RIGHT onto RUSSELL ST. Image from mapquest.com Visualization Success Stories Images from yahoo.com The Special Capabilities of a GIS • In general, a GIS contains two types of data: Spatial data: these elements correspond to a uniquely-defined location on earth. They could be in point, line or polygon form. Attribute data: These are the data that will be portrayed at the geographic references established by spatial data. • Example: Data from an opinion poll is displayed for multiple regions in the United States. Clicking on an area allows the user to drill down to the results for smaller areas. © 2003, Prentice-Hall 52 Telephone Polling Results Note: On the “live” map, clicking on an area allows the user to drill down and see results for smaller areas. © 2003, Prentice-Hall 53 3-7: “Siftware” Technologies Although data visualization product vendors seem to enter or leave the market with great frequency, several firms are beginning to develop significant brand loyalty. Red Brick – Helped category managers at H.E.B. in San Antonio to determine which products to put in which stores. Another application was the consolidation of three old data warehouses at Hewlett-Packard. © 2003, Prentice-Hall 54 Siftware -- Continued SAS – A large suite of statistical analysis software, which allows detailed analysis of large volumes of data. With its add-on product, Enterprise Miner, SAS represents the largest share of the data analysis/mining market place. Cognos – A sophisticated and widely used 3-Dimension visualization software package. © 2003, Prentice-Hall 55 Siftware -- Continued Oracle – A large suite of connectivity products allows transparent access to mainframe databases. Some major customers include John Alden Insurance, ShopKo Stores and Pacific Bell. Informix – Associated Grocers uses Informix data warehousing products at the heart of its three-tier clientserver system. © 2003, Prentice-Hall 56 Siftware -- Continued Sybase – Sybase Warehouse WORKS is an integrated system designed around the four key functions in data warehousing. Silicon Graphics – Data mining software is mated to 3-D visualization tools to allow users to fly through data. IBM – provides a number of decision support tools in its Information Warehouse Solutions. © 2003, Prentice-Hall 57 Visualization in the Aftermath of 9/11 © 2003, Prentice-Hall 58 Six Degrees of Separation of Mohamed Atta http://business2.com/articles/mag/0,1640,35253,FF.html © 2003, Prentice-Hall 59 U.S. Presidential Election 2004 Red Counties=Bush Blue Counties=Kerry © 2003, Prentice-Hall 60 U.S.A. City Population by decade U.S. Census Bureau © 2003, Prentice-Hall 61 © 2003, Prentice-Hall 62 © 2003, Prentice-Hall 63 © 2003, Prentice-Hall 64 © 2003, Prentice-Hall 65 © 2003, Prentice-Hall 66 © 2003, Prentice-Hall 67 © 2003, Prentice-Hall 68 © 2003, Prentice-Hall 69 © 2003, Prentice-Hall 70 © 2003, Prentice-Hall 71 © 2003, Prentice-Hall 72 © 2003, Prentice-Hall 73 © 2003, Prentice-Hall 74 © 2003, Prentice-Hall 75 © 2003, Prentice-Hall 76 © 2003, Prentice-Hall 77 © 2003, Prentice-Hall 78 © 2003, Prentice-Hall 79 © 2003, Prentice-Hall 80 © 2003, Prentice-Hall 81 © 2003, Prentice-Hall 82 © 2003, Prentice-Hall 83 Two Different Primary Goals: Two Different Types of Visualizations Explore/Calculate Analyze Reason about Information Communicate Explain Make Decisions Reason about Information © 2003, Prentice-Hall 84