Title: Business Systems Intelligence: 5. Classification 1
1Business Systems Intelligence5. Classification
1
Dr. Brian Mac Namee (www.comp.dit.ie/bmacnamee)
2Acknowledgments
- These notes are based (heavily) on those
provided by the authors to accompany Data
Mining Concepts Techniques by Jiawei Han
and Micheline Kamber - Some slides are also based on trainers kits
provided by
More information about the book is available
atwww-sal.cs.uiuc.edu/hanj/bk2/ And
information on SAS is available atwww.sas.com
3Classification Prediction
- Today we will look at
- What are classification prediction?
- Issues regarding classification and prediction
- Classification techniques
- Case based reasoning (k-nearest neighbour
algorithm) - Decision tree induction
- Bayesian classification
- Neural networks
- Support vector machines (SVM)
- Classification based on association rule mining
concepts - Other classification methods
- Prediction
- Classification accuracy
4Classification Prediction
- Classification
- Predicts categorical class labels
- Classifies data (constructs a model) based on the
training set and the values (class labels) in a
classifying attribute and uses it in classifying
new data - Prediction
- Models continuous-valued functions, i.e.,
predicts unknown or missing values - Typical Applications
- Credit approval
- Target marketing
- Medical diagnosis
- Treatment effectiveness analysis
5Classification A Two-Step Process
- 1) Model construction
- 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 is
the training set - A model created for classification
6Classification A Two-Step Process (cont)
- 2) Model usage
- Estimate accuracy of the model
- All members of an independent test-set is tested
using the model built - The known label of test sample 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 - If the accuracy is acceptable, the model is used
to classify data tuples whose class labels are
not known
7Classification Model Construction
Classification Algorithm
Training Set
Classification Model
IF rank professor OR years gt 6 THEN tenured
yes
8Classification Using The Model In Prediction
Classifier
Testing Set
Unseen Data
(Jeff, Professor, 4)
Tenured?
Yes
9Supervised 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
10Issues Regarding Classification Prediction
Data Preparation
- Data cleaning
- Preprocess data in order to reduce noise and
handle missing values - Relevance analysis (feature selection)
- Remove the irrelevant or redundant attributes
- Data transformation
- Generalize and/or normalize data
11Issues Regarding Classification Prediction
Evaluating Classification Methods
- Predictive accuracy
- Speed and scalability
- 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
12Classification Techniques Case Based Reasoning
(The k-Nearest Neighbor Algorithm)
- Case based reasoning is a classification
technique which uses prior examples (cases) to
determine the classification of unknown cases - The k-nearest neighbour (k-NN) algorithm is the
simplest form of case based reasoning
13The k-Nearest Neighbor Algorithm)
- All instances correspond to points in n-D space
- The nearest neighbours are defined in terms of
Euclidean distance (or other appropriate measure) - The target value can be discrete or real-valued
- For discrete targets, k-NN returns the most
common value among the k training examples
nearest to the query - For real-valued targets, k-NN returns a
combination (e.g. average) of the nearest
neighbours target values
14Nearest Neighbour Example
Class
Features
Wave Size(ft) Wave Period(secs)
6 15
1 6
5 11
7 10
6 11
2 1
3 4
6 12
4 2
GoodSurf?
Yes
No
Yes
Yes
Yes
No
No
Yes
No
Query
10 10
?
15Nearest Neighbour Example
- When a new case is to be classified
- Calculate the distance from the new case to all
training cases - Put the new case in the same class as its nearest
neighbour
f1
Wave Size
f2
Wave Period
16k-Nearest Neighbour Example
- What about when its too close to call?
- Use the k-nearest neighbour technique
- Determine the k nearest neighbours to the query
case - Put the new case into the same class as the
majority of its nearest neighbours
f1
Wave Size
?
f2
Wave Period
17Nearest Neighbour Distance Measures
- Any kind of measurement can be used to calculate
the distance between cases - The measurement most suitable will depend on the
type of features in the problem - Euclidean distance is the most used technique
- where n is the number of features, ti is the ith
feature of the training case and qi is the ith
feature of the query case
18Summary Of Nearest Neighbour Classification
- Strengths
- No training involved lazy learning
- New data can be added on the fly
- Some explanation capabilities
- Robust to noisy data by averaging k-nearest
neighbors - Weaknesses
- Not the most powerful classification
- Slow classification
- Curse of dimensionality
- One of the easiest machine learning
classification techniques to understand
19Case-Based Reasoning
- Uses lazy evaluation and analysis of similar
instances - However, instances are not necessarily points in
a Euclidean space - Methodology
- Instances represented by rich symbolic
descriptions - Multiple retrieved cases may be combined
- Tight coupling between case retrieval,
knowledge-based reasoning, and problem solving - Lots of active research issues
20Classification Techniques Decision Tree Induction
- Decision trees are the most widely used
classification technique in data mining today - Formulate problems into a tree composed of
decision nodes (or branch nodes) and
classification nodes (or leaf nodes) - Problem is solved by navigating down the tree
until we reach an appropriate leaf node - The tricky bit is building the most efficient and
powerful tree
J. Ross Quinlan is a famed researcher in data
mining and decision theory. He has done
pioneering work in the area of decision trees,
including inventing the ID3 and C4.5 algorithms.
21Training Dataset
Age Income Student CreditRating BuysComputer
lt30 high no fair no
lt30 high no excellent no
31 - 40 high no fair yes
gt40 medium no fair yes
gt40 low yes fair yes
gt40 low yes excellent no
31 - 40 low yes excellent yes
lt30 medium no fair no
lt30 low yes fair yes
gt40 medium yes fair yes
lt30 medium yes excellent yes
31 - 40 medium no excellent yes
31 - 40 high yes fair yes
gt40 medium no excellent no
22Resultant Decision Tree
Age?
lt30
30 - 40
gt40
Student?
Credit Rating?
Yes
no
yes
excellent
fair
Yes
Yes
No
No
23Algorithm For Decision Tree Induction
- Basic algorithm (a greedy algorithm)
- Tree is constructed in a top-down recursive
divide-and-conquer manner - At the start, all the training examples are at
the root - Attributes are categorical (if continuous-valued,
they are discretized in advance) - Examples are partitioned recursively based on
selected attributes - Test attributes are selected on the basis of a
heuristic or statistical measure (e.g.
information gain)
24Algorithm For Decision Tree Induction
- 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
25Attribute Selection Measure Information Gain
(ID3/C4.5)
- The attribute selection mechanism used in ID3 and
based on work on information theory by Claude
Shannon - If our data is split into classes according to
fractions p1,p2, pm then the entropy is
measured as the info required to classify any
arbitrary tuple as follows
26Attribute Selection Measure Information Gain
(ID3/C4.5) (cont)
- The information measure is essentially the same
as entropy - At the root node the information is as follows
27Attribute Selection Measure Information Gain
(ID3/C4.5) (cont)
- To measure the information at a particular
attribute we measure info for the various splits
of that attribute
28Attribute Selection Measure Information Gain
(ID3/C4.5) (cont)
- At the age attribute the information is as
follows
29Attribute Selection Measure Information Gain
(ID3/C4.5) (cont)
- In order to determine which attributes we should
use at each node we measure the information
gained in moving from one node to another and
choose the one that gives us the most information
30Attribute Selection By Information Gain Example
- Class P BuysComputer yes
- Class N BuysComputer no
- I(p, n) I(9, 5) 0.940
- Compute the entropy for age
Age Income Student CreditRating BuysComputer
lt30 high no fair no
lt30 high no excellent no
31 - 40 high no fair yes
gt40 medium no fair yes
gt40 low yes fair yes
gt40 low yes excellent no
31 - 40 low yes excellent yes
lt30 medium no fair no
lt30 low yes fair yes
gt40 medium yes fair yes
lt30 medium yes excellent yes
31 - 40 medium no excellent yes
31 - 40 high yes fair yes
gt40 medium no excellent no
Age pi ni I(pi, ni)
gt30 2 3 0.971
30 40 4 0 0
gt40 3 2 0.971
31Attribute Selection By Information Gain
Computation
- means age lt30 has 5 out of 14
samples, with 2 yes and 3 no. Hence - Similarly
32Other Attribute Selection Measures
- Gini index (CART, IBM IntelligentMiner)
- All attributes are assumed continuous-valued
- Assume there exist several possible split values
for each attribute - May need other tools, such as clustering, to get
the possible split values - Can be modified for categorical attributes
33Extracting Classification Rules From Trees
- Represent knowledge in the form of IF-THEN rules
- One rule is created for each path from root to
leaf - Each attribute-value pair along a path forms a
conjunction - The leaf node holds the class prediction
- Rules are easier for humans to understand
IF Age lt30 AND Student no THEN
BuysComputer no
IF Age lt30 AND Student yes THEN
BuysComputer yes
IF Age 3140 THEN BuysComputer yes
IF Age gt40 AND CreditRating excellent
THEN BuysComputer yes
IF Age lt30 AND CreditRating fair THEN
BuysComputer no
34Overfitting
Training Set
Test Set
35Overfitting (cont)
Training Set
Test Set
36Avoiding Overfitting In Classification
- 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 avoiding overfitting
- Prepruning Halt tree construction early
- Do not split a node if this would result in a
measure of the usefullness of the tree falling
below a threshold - Difficult to choose an appropriate threshold
- Postpruning Remove branches from a fully grown
tree to give a sequence of progressively pruned
trees - Use a set of data different from the training
data to decide which is the best pruned tree
37Approaches To Determine The Final Tree Size
- Separate training (2/3) and testing (1/3) sets
- Use cross validation, e.g., 10-fold cross
validation - Use all the data for training
- But apply a statistical test (e.g., chi-square)
to estimate whether expanding or pruning a node
may improve the entire distribution - Use minimum description length (MDL) principle
- Halting growth of the tree when the encoding is
minimized
38Enhancements To Basic Decision Tree Induction
- Allow for continuous-valued attributes
- Dynamically define new discrete-valued attributes
that partition the continuous attribute value
into a discrete set of intervals - Handle missing attribute values
- Assign the most common value of the attribute
- Assign probability to each of the possible values
- Attribute construction
- Create new attributes based on existing ones that
are sparsely represented - This reduces fragmentation, repetition, and
replication
39Classification In Large Databases
- Classification - a classical problem extensively
studied by statisticians and machine learning
researchers - Scalability Classifying data sets with millions
of examples and hundreds of attributes with
reasonable speed - Why decision tree induction in data mining?
- Relatively faster learning speed (than other
classification methods) - Convertible to simple and easy to understand
classification rules - Can use SQL queries for accessing databases
- Comparable classification accuracy with other
methods
40Data Cube-Based Decision-Tree Induction
- Integration of generalization with decision-tree
induction - Classification at primitive concept levels
- E.g., precise temperature, humidity, outlook,
etc. - Low-level concepts, scattered classes, bushy
classification-trees - Semantic interpretation problems
- Cube-based multi-level classification
- Relevance analysis at multi-levels
- Information-gain analysis with dimension level
41Decision Tree In SAS
42Bayesian Classification Why?
- Probabilistic learning
- Calculate explicit probabilities for a hypothesis
- Among the most practical approaches to certain
types of learning problems - Incremental
- Each training example can incrementally increase/
decrease the probability that a hypothesis is
correct - Prior knowledge can be combined with observed
data - Probabilistic prediction
- Predict multiple hypotheses, weighted by their
probabilities - Standard
- Bayesian methods can provide a standard of
optimal decision making against which other
methods can be measured
43Bayesian Theorem Basics
- Let X be a data sample whose class label is
unknown - Let H be a hypothesis that X belongs to class C
- For classification problems, determine P(HX)
the probability that the hypothesis holds given
the observed data sample X - P(H) prior probability of hypothesis H (i.e. the
initial probability before we observe any data,
reflects the background knowledge) - P(X) probability that sample data is observed
- P(XH) probability of observing the sample X,
given that the hypothesis holds
44Bayesian Theorem
- Given training data X, posteriori probability of
a hypothesis H, P(HX) follows the Bayes theorem -
- Informally, this can be written as
- MAP (maximum posteriori) hypothesis
- Practical difficulty require initial knowledge
of many probabilities, significant computational
cost
posterior (likelihood prior) / evidence
45Naïve Bayes Classifier
- A simplified assumption attributes are
conditionally independent - The product of occurrence of say 2 elements x1
and x2, given the current class is C, is the
product of the probabilities of each element
taken separately, given the same class
P(y1,y2,C) P(y1,C) P(y2,C) - No dependence relation between attributes
- Greatly reduces the computation cost, only count
the class distribution. - Once the probability P(XCi) is known, assign X
to the class with maximum P(XCi)P(Ci)
46Training dataset
Class C1buys_computer yes C2buys_computer
no Data sample X (agelt30, Incomemedium, Stud
entyes Credit_rating Fair)
47Naïve Bayesian Classifier Example
- Compute P(X/Ci) for each class
- P(agelt30 buys_computeryes)
2/90.222 - P(agelt30 buys_computerno) 3/5 0.6
- P(incomemedium buys_computeryes)
4/9 0.444 - P(incomemedium buys_computerno)
2/5 0.4 - P(studentyes buys_computeryes) 6/9
0.667 - P(studentyes buys_computerno)
1/50.2 - P(credit_ratingfair buys_computeryes)
6/90.667 - P(credit_ratingfair buys_computerno)
2/50.4 - X(agelt30 ,income medium, studentyes,credit_
ratingfair) - P(XCi) P(Xbuys_computeryes) 0.222 x
0.444 x 0.667 x 0.0.667 0.044 - P(Xbuys_computerno) 0.6 x
0.4 x 0.2 x 0.4 0.019 - P(XCi)P(Ci ) P(Xbuys_computeryes)
P(buys_computeryes)0.028 - P(Xbuys_computerno)
P(buys_computerno)0.007 - X belongs to class buys_computeryes
48Naïve Bayesian Classifier Comments
- Advantages
- Easy to implement
- Good results obtained in most of the cases
- Disadvantages
- Assumption class conditional independence ,
therefore loss of accuracy - Practically, dependencies exist among variables
- E.g., hospitals patients Profile age, family
history etc - Symptoms fever, cough etc., Disease lung
cancer, diabetes etc - Dependencies among these cannot be modeled by
Naïve Bayesian Classifier - How to deal with these dependencies?
- Bayesian Belief Networks
49Bayesian Networks
- Bayesian belief network allows a subset of the
variables conditionally independent - A graphical model of causal relationships
- Represents dependency among the variables
- Gives a specification of joint probability
distribution
- Nodes random variables
- Links dependency
- X,Y are the parents of Z, and Y is the parent of
P - No dependency between Z and P
- Has no loops or cycles
X
50Bayesian Belief Network An Example
Family History
Smoker
(FH, S)
(FH, S)
(FH, S)
(FH, S)
LC
0.7
0.8
0.5
0.1
LungCancer
Emphysema
LC
0.3
0.2
0.5
0.9
The conditional probability table for the
variable LungCancer Shows the conditional
probability for each possible combination of its
parents
PositiveXRay
Dyspnea
Bayesian Belief Networks
51Learning Bayesian Networks
- Several cases
- Given both the network structure and all
variables observable learn only the CPTs - Network structure known, some hidden variables
method of gradient descent, analogous to neural
network learning - Network structure unknown, all variables
observable search through the model space to
reconstruct graph topology - Unknown structure, all hidden variables no good
algorithms known for this purpose - D. Heckerman, Bayesian networks for data mining
52Lazy Vs. Eager Learning
- Lazy learning
- Case based reasoning
- Eager learning
- Decision-tree and Bayesian classification
- Key differences
- Lazy method may consider query instance when
deciding how to generalize beyond the training
data D - Eager method cannot since they have already
chosen global approximation when seeing the query
53Lazy Vs. Eager Learning
- Efficiency
- Lazy, less time training but more time predicting
- Accuracy
- Lazy method effectively uses a richer hypothesis
space since it uses many local linear functions
to form its implicit global approximation to the
target function - Eager learners must commit to a single hypothesis
that covers the entire instance space - Easier for lazy learners to cope with concept
drift
54Summary
- Classification is an extensively studied problem
- Classification is probably one of the most widely
used data mining techniques with a lot of
extensions - Classification techniques can be categorized as
either lazy or eager - Scalability is still an important issue for
database applications thus combining
classification with database techniques should be
a promising topic - Research directions classification of
non-relational data, e.g., text, spatial,
multimedia, etc. classification of skewed data
sets
55Questions?