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ML410C Projects in health informatics – Project and information management Data Mining
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Last time… Why do we need data analysis? What is data mining?
Examples where data mining has been useful Data mining and other areas of computer science and mathematics Some (basic) data mining tasks
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The Knowledge Discovery Process
Knowledge Discovery in Databases (KDD) is the nontrivial process of identifying valid, novel, potentially useful, and ultimately understandable patterns in data. U.M. Fayyad, G. Piatetsky-Shapiro and P. Smyth, “From Data Mining to Knowledge Discovery in Databases”, AI Magazine 17(3): (1996)
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CRISP-DM: CRoss Industry Standard Process for Data Mining
Shearer C., “The CRISP-DM model: the new blueprint for data mining”, Journal of Data Warehousing 5 (2000) (see also
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Today DATE TIME ROOM TOPIC MONDAY 2013-09-09 10:00-11:45 502
Introduction to data mining WEDNESDAY 09:00-10:45 501 Decision trees, rules and forests FRIDAY Sal C Evaluating predictive models and tools for data mining
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Today What is classification Overview of classification methods
Decision trees Forests
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Predictive data mining
Our task Input: data representing objects that have been assigned labels Goal: accurately predict labels for new (previously unseen) objects
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An example: email classification
Features (attributes) Ex. All caps No. excl. marks Missing date No. digits in From: Image fraction Spam e1 yes no 3 e2 0.2 e3 1 e4 4 0.5 e5 2 e6 Examples (observations)
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Decision tree Spam = yes Spam = yes Spam = no
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Rules Spam = yes Spam = no Spam = yes Spam = no Spam = no
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Forests 11
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Classification What is the class of the following e-mail? No Caps: Yes
No. excl. marks: 0 Missing date: Yes No. digits in From: 4 Image fraction: 0.3
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Classification What is classification?
Issues regarding classification and prediction Classification by decision tree induction Classification by Naïve Bayes classifier Classification by Nearest Neighbor Classification by Bayesian Belief networks
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Classification Classification: Typical Applications
predicts categorical class labels classifies data (constructs a model) based on the training set and the values (class labels) in a classifying attribute uses the model for classifying new data Typical Applications credit approval target marketing medical diagnosis treatment effectiveness analysis
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Why Classification? A motivating application
Credit approval A bank wants to classify its customers based on whether they are expected to pay back their approved loans The history of past customers is used to train the classifier The classifier provides rules, which identify potentially reliable future customers
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Why Classification? A motivating application
Credit approval Classification rule: If age = “ ” and income = high then credit_rating = excellent Future customers Paul: age = 35, income = high excellent credit rating John: age = 20, income = medium fair credit rating
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Classification—A Two-Step Process
Model construction: describing a set of predetermined classes Each tuple/sample is assumed to belong to a predefined class, as determined by the class label attribute The set of tuples used for model construction: training set The model is represented as classification rules, decision trees, or mathematical formulas
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Classification—A Two-Step Process
Model usage: for classifying future or unknown objects Estimate accuracy of the model The known label of test samples is compared with the classified result from the model Accuracy rate is the percentage of test set samples that are correctly classified by the model Test set is independent of training set, otherwise over-fitting will occur
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Classification Process (1): Model Construction
Algorithms Training Data Classifier (Model) IF LDL = ‘high’ OR Gluc > 6 mmol/lit THEN Heart attack = ‘yes’
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Classification Process (2): Use the Model in Prediction
Classifier Accuracy=? Testing Data Unseen Data (Jeff, high, 7.5) Heart attack?
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Supervised vs. Unsupervised Learning
Supervised learning (classification) Supervision: The training data (observations, measurements, etc.) are accompanied by labels indicating the class of the observations New data is classified based on the training set Unsupervised learning (clustering) The class labels of training data is unknown Given a set of measurements, observations, etc. with the aim of establishing the existence of classes or clusters in the data
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Issues regarding classification and prediction: Evaluating Classification Methods
Predictive accuracy Speed time to construct the model time to use the model Robustness handling noise and missing values Scalability efficiency in disk-resident databases Interpretability: understanding and insight provided by the model Goodness of rules (quality) decision tree size compactness of classification rules
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Classification by Decision Tree Induction
A flow-chart-like tree structure Internal node denotes a test on an attribute Branch represents an outcome of the test Leaf nodes represent class labels or class distribution Decision tree generation consists of two phases Tree construction At start, all the training examples are at the root Partition examples recursively based on selected attributes Tree pruning Identify and remove branches that reflect noise or outliers Use of decision tree: Classifying an unknown sample Test the attribute values of the sample against the decision tree
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Training Dataset Example
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Output: A Decision Tree for “buys_computer”
age? <=30 overcast 30..40 >40 student? yes credit rating? no yes excellent fair no yes no yes
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Algorithm for Decision Tree Induction
Basic algorithm (a greedy algorithm) Tree is constructed in a top-down recursive divide-and-conquer manner At start, all the training examples are at the root Attributes are categorical (if continuous-valued, they are discretized in advance) Samples are partitioned recursively based on selected attributes Test (split) attributes are selected on the basis of a heuristic or statistical measure (e.g., information gain) Conditions for stopping partitioning All samples for a given node belong to the same class There are no remaining attributes for further partitioning – majority voting is employed for classifying the leaf There are no samples left
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Algorithm for Decision Tree Induction (pseudocode)
Algorithm GenDecTree(Sample S, Attlist A) create a node N If all samples are of the same class C then label N with C; terminate; If A is empty then label N with the most common class C in S (majority voting); terminate; Select aA, with the highest information gain; Label N with a; For each value v of a: Grow a branch from N with condition a=v; Let Sv be the subset of samples in S with a=v; If Sv is empty then attach a leaf labeled with the most common class in S; Else attach the node generated by GenDecTree(Sv, A-a)
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Attribute Selection Measure: Information Gain
Let pi be the probability that an arbitrary tuple in D belongs to class Ci, estimated by |Ci, D|/|D| - where Ci, D denotes the set of tuples that belong to class Ci Expected information (entropy) needed to classify a tuple in D: - where m is the number of classes I : the expected information needed to classify a given sample E (entropy) : expected information based on the partitioning into subsets by A
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Attribute Selection Measure: Information Gain
Information needed (after using A to split D into v partitions) to classify D: Information gained by branching on attribute A I : the expected information needed to classify a given sample E (entropy) : expected information based on the partitioning into subsets by A
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Attribute Selection: Information Gain
Class P: buys_computer = “yes” Class N: buys_computer = “no”
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Splitting the samples using age
<=30 >40 labeled yes
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Gini index If a data set D contains examples from n classes, gini index, gini(D) is defined as - where pj is the relative frequency of class j in D If a data set D is split on A into two subsets D1 and D2, the gini index gini(D) is defined as
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Gini index Reduction in Impurity:
The attribute that provides the smallest ginisplit(D) (or the largest reduction in impurity) is chosen to split the node
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Gini index (CART, IBM IntelligentMiner)
Example: D has 9 tuples in buys_computer = “yes” and 5 in “no” Suppose that attribute “income” partitions D into 10 records (D1: {low, medium}) and 4 records (D2: {high}).
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Gini index Then: = 0.45 and gini{medium,high} = 0.30
All attributes are assumed continuous-valued May need other tools, e.g., clustering, to get the possible split values
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Comparing Attribute Selection Measures
The two measures, in general, return good results but Information gain: biased towards multivalued attributes Gini index: biased to multivalued attributes has difficulty when # of classes is large tends to favor test sets that result in equal-sized partitions and purity in both partitions
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Overfitting due to noise
Decision boundary is distorted by noise point
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Overfitting due to insufficient samples
Why?
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Overfitting due to insufficient samples
Lack of data points in the lower half of the diagram makes it difficult to predict correctly the class labels of that region - Insufficient number of training records in the region causes the decision tree to predict the test examples using other training records that are irrelevant to the classification task
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Overfitting and Tree Pruning
Overfitting: An induced tree may overfit the training data Too many branches, some may reflect anomalies due to noise or outliers Poor accuracy for unseen samples Two approaches to avoid overfitting Prepruning: Halt tree construction early—do not split a node if this would result in the goodness measure falling below a threshold Difficult to choose an appropriate threshold Postpruning: Remove branches from a “fully grown” tree—get a sequence of progressively pruned trees
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Occam’s Razor “entia non sunt multiplicanda praeter ecessitatem”,
Given two models of similar generalization errors, one should prefer the simpler model over the more complex model Therefore, one should include model complexity when evaluating a model “entia non sunt multiplicanda praeter ecessitatem”, which translates to: “entities should not be multiplied beyond necessity”.
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Pros and Cons of decision trees
Reasonable training time Fast application Easy to interpret Easy to implement Can handle large number of features Cons Cannot handle complicated relationship between features simple decision boundaries problems with lots of missing data
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Some well-known decision tree learning implementations
CART Breiman L, Friedman JH, Olshen RA, Stone CJ (1984) Classification and Regression Trees. Wadsworth ID3 Quinlan JR (1986) Induction of decision trees. Machine Learning 1:81–106 C4.5 Quinlan JR (1993) C4.5: Programs for machine learning. Morgan Kaufmann J48 Implementation of C4.5 in WEKA
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Handling missing values
Remove attributes with missing values Remove examples with missing values Assume most frequent value Assume most frequent value given a class Learn the distribution of a given attribute Find correlation between attributes
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Handling missing values
Example A 1 … Class e1 yes + e2 no e3 - e4 ? A1 yes no e1 (w=1) e3 (w=1) e4 (w=2/3) e2 (w=1) e4 (w=1/3)
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k-nearest neighbor classifiers
k-nearest neighbors of a record x are data points that have the k smallest distance to x
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k-nearest neighbor classification
Given a data record x find its k closest points Closeness: ? Determine the class of x based on the classes in the neighbor list Majority vote Weigh the vote according to distance e.g., weight factor, w = 1/d2
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Characteristics of nearest-neighbor classifiers
No model building (lazy learners) Lazy learners: computational time in classification Eager learners: computational time in model building Decision trees try to find global models, k-NN take into account local information K-NN classifiers depend a lot on the choice of proximity measure
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Condorcet’s jury theorem
If each member of a jury is more likely to be right than wrong, then the majority of the jury, too, is more likely to be right than wrong and the probability that the right outcome is supported by a majority of the jury is a (swiftly) increasing function of the size of the jury, converging to 1 as the size of the jury tends to infinity Condorcet, 1785 49
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Condorcet’s jury theorem
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Random forests Random forests (Breiman 2001) are generated by combining two techniques: bagging (Breiman 1996) the random subspace method (Ho 1998) L. Breiman. Random forests. Machine Learning, 45(1):5–32, 2001 L. Breiman. Bagging predictors. Machine Learning, 24(2):123–140, 1996 T. K. Ho. The random subspace method for constructing decision forests, IEEE Transactions on Pattern Analysis and Machine Intelligence, 20(8): , 1998 51
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Bagging A bootstrap replicate E’ of a set of examples E is created by
Other Bar Fri/Sat Hungry Guests Wait e2 yes no full e3 some e4 e6 Ex. Other Bar Fri/Sat Hungry Guests Wait e1 yes no some e2 full e3 e4 e5 none e6 A bootstrap replicate E’ of a set of examples E is created by randomly selecting n = |E| examples from E with replacement.
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Forests 53
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Today What is classification Overview of classification methods
Decision trees Forests
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Next time DATE TIME ROOM TOPIC MONDAY 2013-09-09 10:00-11:45 502
Introduction to data mining WEDNESDAY 09:00-10:45 501 Decision trees, rules and forests FRIDAY Sal C Evaluating predictive models and tools for data mining
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