Line 9: | Line 9: | ||
* Background in Linear Classifiers | * Background in Linear Classifiers | ||
− | |||
* Support Vector Machine | * Support Vector Machine | ||
+ | * Effect of parameters on SVM | ||
* Summary | * Summary | ||
* References | * References | ||
Line 76: | Line 76: | ||
− | In many applications the data is not linearly separable, in this case 'kernel trick' is applied to map the data into high-dimensional feature spaces. | + | In many applications the data is not linearly separable, in this case 'kernel trick' is applied to map the data into high-dimensional feature spaces. We fist map the input space to a feature space using <math>\varphi: \mathbb{R}^n \rightarrow \mathbb{R}^m</math> |
− | + | Then the discriminant function is then | |
− | <center><math> k: \mathbb{R}^n \times \mathbb{R}^n to \mathbb{R} | + | <center><math> f(\textbf{y} = \textbf{c}^T\varphi(\textbf{y})) + b. </math></center> |
+ | |||
+ | Suppose <math> \textbf{c} = \sum_{i=1}^{n}\alpha_i\textbf{y}_i</math>, | ||
+ | then the discriminant function in the new feature space takes the form: | ||
+ | <center><math> f(\textbf{y}) = \sum_{i=1}^{n}\alpha_i\varphi(\textbf{y}_i)^T\varphi(\textbf{y})+b </math></center> | ||
+ | |||
+ | By defining a kernel function as a mapping function: | ||
+ | <center><math> k: \mathbb{R}^n \times \mathbb{R}^n to \mathbb{R} </math></center> | ||
that satisfies: | that satisfies: | ||
+ | <center><math> k(\textbf{y}_i,\textbf{y}_j) = \varphi(\textbf{y}_i)^T\varphi(\textbf{y}_j). </math></center> | ||
+ | The discriminant function in terms of the kernel function is | ||
+ | <center><math> f(\textbf{y}) = \sum_{i=1}^n\alpha_i k(\textbf{y},\textbf{y}_i)+b. </math></center> | ||
− | The | + | The resulting algorithm is formally similar, except that every dot product is replaced by a nonlinear kernel function. |
+ | == Effect of parameters on SVM == |
Revision as of 06:21, 4 May 2014
'Support Vector Machine and its Applications in Classification Problems
A slecture by Xing Liu
Partially based on the ECE662 Spring 2014 lecture material of Prof. Mireille Boutin.
Contents
Outline of the slecture
- Background in Linear Classifiers
- Support Vector Machine
- Effect of parameters on SVM
- Summary
- References
Background in Linear Classifiers
In this section, we will introduce the framework and basic idea of linear classification problem.
In a linear classification problem, the feature space can be divided into different regions by hyperplanes. In this lecture, we will take a two-catagory case to illustrate. Given training samples $ \textbf{y}_1,\textbf{y}_2,...\textbf{y}_n \in \mathbb{R}^p $, each $ \textbf{y}_i $ is a p-dimensional vector and belongs to either class $ w_1 $ or $ w_2 $. The goal is to find the maximum-margin hyperplane that separate the points in the feature space that belong to class $ w_1 $ from those that belong to class $ w_2 $. The discriminate function can be written as
We want to find $ \textbf{c}\in\mathbb{R}^{n+1} $ so that a testing data point $ \textbf{y}_i $ is labelled
We can apply a trick here to replace all $ \textbf{y} $'s in class $ w_2 $ by $ -\textbf{y} $, then the above task is equivalent to looking for $ \textbf{c} $ so that
You might have already observed the ambiguity of c in the above discussion: if c separates data, $ \lambda \textbf{c} $ also separates the data. One solution might be set $ |\textbf{c}|=1 $. Another solution is to introduce a bias denoted b, and ask
In this scenario, the hyperplane is defined by $ \{\textbf{y}: f(\textbf{y})=\textbf{c}\cdot \textbf{y} - \textbf{b}=0\} $ and it divides the space into two, the sign of the discriminant function $ f(\textbf{y}) = \textbf{c}\cdot \textbf{y} - \textbf{b} $ denotes the side of the hyperplane a testing point is on. We notice that he decision boundary by this hyperplane is linear, hence the classifier is called a linear classifier. $ \textbf{c} $ is the normal of the plane lying on the positive side of every hyperplane. $ \frac{b_i}{||c||} $ is the distance from each point $ \textbf{y}_i $ to the hyperplane. We notice that he decision boundary by this hyperplane is linear, hence the classifier is called a linear classifier.
The above approach is equivalent to finding a solution for
where $ \textbf{Y} =\begin{bmatrix} y_1^T \\ y_2^T \\ ... \\ y_n^T \end{bmatrix} $
In most cases when n>p, it is always impossible to find a solution for $ \textbf{c} $. An alternative approach is to find c that minimize a criterion function $ J(\textbf{c}) $. There are variant forms of criterion functions. For example, we can try to minimize the error vector between $ \textbf{c}\cdot\textbf{y} $ and $ b $, hence the criterion function can be defined as
The solution to the above problem is
if $ det(\textbf{Y}^T\textbf{Y})\neq 0 $
otherwise, the solution is defined generally by
This solution is a MSE solution to $ \textbf{Y}\textbf{c} = \textbf{b} $and it always exists.
Support Vector Machine
Support vector machines are an example of a linear two-class classifier. For a given hyperlane we denote by $ \textbf{y}_1,\textbf{y}_2 $ the closest point to the hyperpalne among the positive (negative). The distance from the two points to the hyperplane is $ g(\textbf{y}_1)/||c|| $ and $ g(\textbf{y}_2)/||c|| $. The margin is defined as the region between the two points. In SVM, the hyperplane is chosen so that the margin is maximized, i.e. we want to maximize 1/||c||, which is equivalent to minimizing $ ||c||^2 $. This leads to the following optimization problem:
A more general classifier that allows misclassfication would be
where ξi ≥ 0 are slack variables that allow an example to be in the margin (0 ≤ ξi ≤ 1, also called a margin error) or to be misclassified (ξi > 1). The constant C > 0 sets the relative importance of maximizing the margin and minimizing the amount of slack. Using the method of Lagrange multipliers, we can obtain the dual formulation which is expressed in terms of variables αi:
In many applications the data is not linearly separable, in this case 'kernel trick' is applied to map the data into high-dimensional feature spaces. We fist map the input space to a feature space using $ \varphi: \mathbb{R}^n \rightarrow \mathbb{R}^m $
Then the discriminant function is then
Suppose $ \textbf{c} = \sum_{i=1}^{n}\alpha_i\textbf{y}_i $, then the discriminant function in the new feature space takes the form:
By defining a kernel function as a mapping function:
that satisfies:
The discriminant function in terms of the kernel function is
The resulting algorithm is formally similar, except that every dot product is replaced by a nonlinear kernel function.