Support Vector Machines: Optimization Based Theory, Algorithms, and Extensions presents an accessible treatment of the two main components of support vector machines (SVMs)—classification problems and regression problems. The book emphasizes the close connection between optimization theory and SVMs since optimization is one of the pillars on which SVMs are built.
The authors share insight on many of their research achievements. They give a precise interpretation of statistical leaning theory for C-support vector classification. They also discuss regularized twin SVMs for binary classification problems, SVMs for solving multi-classification problems based on ordinal regression, SVMs for semi-supervised problems, and SVMs for problems with perturbations.
To improve readability, concepts, methods, and results are introduced graphically and with clear explanations. For important concepts and algorithms, such as the Crammer-Singer SVM for multi-class classification problems, the text provides geometric interpretations that are not depicted in current literature.
Enabling a sound understanding of SVMs, this book gives beginners as well as more experienced researchers and engineers the tools to solve real-world problems using SVMs.
This book provides a concise overview of support vector machines (SVMs), starting from the basics and connecting to many of their most significant extensions. Starting from an optimization perspective provides a new way of presenting the material, including many of the technical details that are hard to find in other texts. And since it includes a discussion of many practical issues important for the effective use of SVMs (e.g., feature construction), the book is valuable as a reference for researchers and practitioners alike.
—Thorsten Joachims, Associate Professor, Department of Computer Science, Cornell University
The books on support vector machines (SVMs) in Chinese written by the same authors are very popular in China. It is really great that the authors have translated the books into English and made further extensions on them. One thing which makes the book very unique from the other books is that the authors try to shed light on SVM from the viewpoint of optimization. I believe that the comprehensive and systematic explanation on the basic concepts, fundamental principles, algorithms, and theories of SVM will help readers have a really in-depth understanding of the space. It is really a great book, which many researchers, students, and engineers in computer science and related fields will want to carefully read and routinely consult.
—Dr. Hang Li, Chief Scientist of Noah’s Ark Lab, Huawei Technologies Co., Ltd
This book comprehensively covers many topics of support vector machines (SVMs). In particular, it gives a nice connection between optimization theory and support vector machines. In my experience of developing the popular SVM software LIBSVM, I found that many users lack a good understanding of the optimization concept behind SVM. This book starts with explaining basic knowledge of convex optimization and then introduces linear support vector classification and regression. Next, it discusses kernel SVM and the practical implementation. The setting allows readers to easily learn how optimization techniques are used in a machine learning technique such as SVM.
—Chih-Jen Lin, Professor, Department of Computer Science, National Taiwan University
Optimization Problems in Euclidian Space
Convex Programming in Euclidean Space
Convex Programming in Hilbert Space
Convex Programming with Generalized Inequality Constraints in Rn
Convex Programming with Generalized Inequality Constraints in Hilbert Space
Linear Classification Machines
Presentation of Classification Problems
Support Vector Classification (SVC) for Linearly Separable Problems
Linear Support Vector Classification
Linear Regression Machines
Regression Problems and Linear Regression Problems
Hard ε-Band Hyperplane
Linear Hard ε-Band Support Vector Regression
Linear ε-Support Vector Regression
Kernels and Support Vector Machines
From Linear Classification to Nonlinear Classification
Support Vector Machines and Their Properties
Meaning of Kernels
Basic Statistical Learning Theory of C-Support Vector Classification
Classification Problems on Statistical Learning Theory
Empirical Risk Minimization
Vapnik Chervonenkis (VC) Dimension
Structural Risk Minimization
An Implementation of Structural Risk Minimization
Theoretical Foundation of C-Support Vector Classification on Statistical Learning Theory
Sequential Minimal Optimization
Variants and Extensions of Support Vector Machines
Variants of Binary Classification
Variants of Regression