Machine Learning: A Practical Approach on the Statistical Learning Theory

Chapter 1 - A Brief Review on Machine Learning

1.1 Machine Learning definition

1.2 Main types of learning

1.3 Supervised learning

1.4 How a supervised algorithm learns?

1.5 Illustrating the Supervised Learning

1.51. The Perceptron

1.5.2 Multilayer Perceptron

1.6 Concluding Remarks

Chapter 2 - Statistical Learning Theory

2.1 Motivation

2.2 Basic concepts

2.2.1 Probability densities and joint probabilities

2.2.3 Assumptions considered by the Statistical Learning Theory

2.2.4 Expected risk and generalization

2.2.5 Bounds for generalization with a practical example

2.2.6 Bayes risk and universal consistency

2.2.7 Consistency, overfitting and underfitting

2.2.8 Bias of classification algorithms

2.3 Empirical Risk Minimization Principle

2.3.1 Consistency and the ERM Principle

2.3.3 Ensuring uniform convergence in practice

2.4 Symmetrization lemma and the shattering coefficient

2.4.1 Shattering coefficient as a capacity measure

2.4.2 Making the ERM Principle consistent for infinite functions

2.5 Generalization bounds

2.6 The Vapnik-Chervonenkis dimension

2.6.1 Margin bounds

2.7 Concluding Remarks

Chapter 3 - Assessing Learning Algorithms

3.1 Mapping the concepts of the Statistical Learning Theory

3.2 Using the Chernoff bound

3.3 Using the Generalization Bound

3.4 Using the SVM Generalization Bound

3.5 Empirical Study of the Biases of Classification Algorithms

3.6 Concluding Remarks

Chapter 4 - Introduction to Support Vector Machines

4.1 Using basic Algebra to build a classification algorithm

4.2 Hyperplane-based classification: an intuitive view

4.3 Hyperplane-based classification: an algebraic view

4.3.1 Lagrange multipliers

4.3.2 Karush-Kuhn-Tucker conditions

4.4 Formulating the hard-margin SVM optimization problem

4.5 Formulating the soft-margin SVM optimization problem

4.6 Concluding Remarks

Chapter 5 - In Search for the Optimization Algorithm

5.1 What is an optimization problem?

5.2 Main types of optimization problems

5.3 Linear optimization problems

5.3.1 Solving through graphing

5.3.2 Primal and dual forms of linear problems

5.3.2.1 Using the table and rules

5.3.2.2 Graphical interpretation of primal and dual forms

5.3.3 Using an algorithmic approach to solve linear problems

5.3.4 On the KKT conditions for linear problems

5.3.4.1 Applying the rules

5.3.4.2 Graphical interpretation of the KKT conditions

5.4 Convex optimization problems

5.4.1 Interior Point Methods

5.4.2 The Primal-Dual Path Following Interior Point Method

5.4.3 Implementing the Interior Point Method to solve our first optimization problem

5.4.5 Solving the SVM optimization problem using package LowRankQP

5.5 Concluding Remarks

Chapter 6 - A Brief Introduction on Kernels

6.1 Definitions, typical kernels and examples

6.1.1 The Polynomial kernel

6.1.2 The Radial Basis Function kernel

6.1.3 The Sigmoidal Kernel

6.1.4 Practical examples with kernels

6.2 Linear Algebra

6.2.1 Basis

6.2.2 Linear transformation

6.2.4 Dot products

6.2.5 Change of basis and orthonormal basis

6.2.6 Eigenvalues and Eigenvectors

6.3 Principal Component Analysis (PCA)

6.4 Kernel Principal Component Analysis (KPCA)

6.5 Assessing Kernels using Practical Problems

6.6 SVM Kernel trick

6.7 A quick note on the Mercer's theorem

6.8 Conclusions