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Transcript
Supervised Learning
Regression, Classification
Linear regression, k-NN classification
Debapriyo Majumdar
Data Mining – Fall 2014
Indian Statistical Institute Kolkata
August 11, 2014
Power (bhp)
An Example: Size of Engine vs Power
200
180
160
140
120
100
80
60
40
20
0
0
500
1000
1500
2000
2500
Engine displacement (cc)
 An unknown car has an engine of size 1800cc. What is likely
to be the power of the engine?
2
Power (bhp)
An Example: Size of Engine vs Power
Target
Variable
200
180
160
140
120
100
80
60
40
20
0
0
500
1000
1500
2000
2500
Engine displacement (cc)
 Intuitively, the two variables have a relation
 Learn the relation from the given data
 Predict the target variable after learning
3
Exercise: on a simpler set of data points
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x
1
2
3
4
2.5
10
y
8
6
4
2
y
1
3
7
10
?
0
0
1
2
3
4
5
x
 Predict y for x = 2.5
4
Power (bhp)
Linear Regression
200
180
160
140
120
100
80
60
40
20
0
Training set
0
500
1000
1500
2000
2500
Engine displacement (cc)
 Assume: the relation is linear
 Then for a given x (=1800), predict the value of y
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Power (bhp)
Linear Regression
200
180
160
140
120
100
80
60
40
20
0
0
500
1000
1500
2000
2500
Engine Power
(cc) (bhp)
800
60
1000
90
1200
80
1200
100
1200
75
1400
90
1500
120
1800
160
2000
140
2000
170
2400
180
Engine displacement (cc)
 Linear regression
 Assume y = a . x + b
 Try to find suitable a and b
Optional exercise
6
Exercise: using Linear Regression
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x
1
2
3
4
2.5
10
y
8
6
4
2
y
1
3
7
10
?
0
0
1
2
3
4
5
x
 Define a regression line of your choice
 Predict y for x = 2.5
7
Choosing the parameters right
200
Goal: minimizing
the deviation from
the actual data
points
150
y
100
50
0
0




500
1000
x
1500
2000
2500
The data points: (x1, y1), (x2, y2), … , (xm, ym)
The regression line: f(x) = y = a . x + b
Least-square cost function: J = Σi ( f(xi) – yi )2
Goal: minimize J over choices of a and b
8
How to Minimize the Cost Function?
b
a




Goal: minimize J for all values of a and b
Start from some a = a0 and b = b0
Compute: J(a0,b0)
Simultaneously change a and b towards the negative
gradient and eventually hope to arrive an optimal
 Question: Can there be more than one optimal?
Δ
9
Another example:
High blood sugar
Y
Training set
N
0
20
40
60
80
Age
 Given that a person’s age is 24, predict if (s)he has
high blood sugar
 Discrete values of the target variable (Y / N)
 Many ways of approaching this problem
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Classification problem
High blood sugar
Y
N
?
0
20
24
40
60
80
Age
 One approach: what other data points are nearest to
the new point?
 Other approaches?
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Classification Algorithms






The k-nearest neighbor classification
Naïve Bayes classification
Decision Tree
Linear Discriminant Analysis
Logistics Regression
Support Vector Machine
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Classification or Regression?
Given data about some cars: engine size, number of
seats, petrol / diesel, has airbag or not, price
 Problem 1: Given engine size of a new car, what is
likely to be the price?
 Problem 2: Given the engine size of a new car, is it
likely that the car is run by petrol?
 Problem 3: Given the engine size, is it likely that the
car has airbags?
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Classification
Example: Age, Income and Owning a flat
Monthly income
(thousand rupees)
250
Training set
• Owns a
flat
200
150
• Does
not own
a flat
100
50
0
0
10
20
30
40
50
60
70
Age
 Given a new person’s age and income, predict – does
(s)he own a flat?
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Example: Age, Income and Owning a flat
Monthly income
(thousand rupees)
250
Training set
• Owns a
flat
200
150
• Does
not own
a flat
100
50
0
0
10
20
30
40
50
60
70
Age
 Nearest neighbor approach
 Find nearest neighbors among the known data points
and check their labels
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Example: Age, Income and Owning a flat
Monthly income
(thousand rupees)
250
Training set
• Owns a
flat
200
150
• Does
not own
a flat
100
50
0
0
10
20
30
40
50
60
70
Age
 The 1-Nearest Neighbor (1-NN) Algorithm:
– Find the closest point in the training set
– Output the label of the nearest neighbor
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The k-Nearest Neighbor Algorithm
Monthly income
(thousand rupees)
250
Training set
• Owns a
flat
200
150
• Does
not own
a flat
100
50
0
0
10
20
30
40
50
60
70
Age
 The k-Nearest Neighbor (k-NN) Algorithm:
– Find the closest k point in the training set
– Majority vote among the labels of the k points
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Distance measures
 How to measure distance to find closest points?
 Euclidean: Distance between vectors x = (x1, … , xk)
and y = (y1, … , yk)
 Manhattan distance:
 Generalized squared interpoint distance: S is the
covariance matrix
The Maholanobis distance (1936)
19
Classification setup
 Training data / set: set of input data points and given
answers for the data points
 Labels: the list of possible answers
 Test data / set: inputs to the classification algorithm
for finding labels
– Used for evaluating the algorithm in case the answers are
known (but known to the algorithm)
 Classification task: Determining labels of the data
points for which the label is not known or not passed
to the algorithm
 Features: attributes that represent the data
20
Evaluation
 Test set accuracy: the correct performance measure
 Accuracy = #of correct answer / #of all answers
 Need to know the true test labels
– Option: use training set itself
– Parameter selection (for k-NN) by accuracy on training set
 Overfitting: a classifier performs too good on training
set compared to new (unlabeled) test data
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Better validation methods
 Leave one out:
–
–
–
–
–
For each training data point x of training set D
Construct training set D – x, test set {x}
Train on D – x, test on x
Overall accuracy = average over all such cases
Expensive to compute
 Hold out set:
– Randomly choose x% (say 25-30%) of the training data, set
aside as test set
– Train on the rest of training data, test on the test set
– Easy to compute, but tends to have higher variance
22
The k-fold Cross Validation Method
 Randomly divide the training data into k partitions
D1,…, Dk : possibly equal division
 For each fold Di
– Train a classifier with training data = D – Di
– Test and validate with Di
 Overall accuracy: average accuracy over all cases
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References
 Lecture videos by Prof. Andrew Ng, Stanford University
Available on Coursera (Course: Machine Learning)
 Data Mining Map: http://www.saedsayad.com/
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