2014-11-27 20:39:05 +08:00
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Introduction to Support Vector Machines {#tutorial_introduction_to_svm}
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=======================================
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2020-12-08 00:13:54 +08:00
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@tableofcontents
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2020-12-05 06:46:00 +08:00
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@prev_tutorial{tutorial_traincascade}
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2020-05-20 06:59:28 +08:00
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@next_tutorial{tutorial_non_linear_svms}
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2020-12-05 06:46:00 +08:00
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| Original author | Fernando Iglesias García |
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| Compatibility | OpenCV >= 3.0 |
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2014-11-27 20:39:05 +08:00
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Goal
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----
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In this tutorial you will learn how to:
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2014-11-28 00:54:13 +08:00
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- Use the OpenCV functions @ref cv::ml::SVM::train to build a classifier based on SVMs and @ref
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cv::ml::SVM::predict to test its performance.
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What is a SVM?
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--------------
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A Support Vector Machine (SVM) is a discriminative classifier formally defined by a separating
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hyperplane. In other words, given labeled training data (*supervised learning*), the algorithm
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outputs an optimal hyperplane which categorizes new examples.
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In which sense is the hyperplane obtained optimal? Let's consider the following simple problem:
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For a linearly separable set of 2D-points which belong to one of two classes, find a separating
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straight line.
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2014-11-28 21:21:28 +08:00
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![](images/separating-lines.png)
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@note In this example we deal with lines and points in the Cartesian plane instead of hyperplanes
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and vectors in a high dimensional space. This is a simplification of the problem.It is important to
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understand that this is done only because our intuition is better built from examples that are easy
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to imagine. However, the same concepts apply to tasks where the examples to classify lie in a space
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whose dimension is higher than two.
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2015-02-11 18:24:14 +08:00
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In the above picture you can see that there exists multiple lines that offer a solution to the
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problem. Is any of them better than the others? We can intuitively define a criterion to estimate
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the worth of the lines: <em> A line is bad if it passes too close to the points because it will be
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noise sensitive and it will not generalize correctly. </em> Therefore, our goal should be to find
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the line passing as far as possible from all points.
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Then, the operation of the SVM algorithm is based on finding the hyperplane that gives the largest
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minimum distance to the training examples. Twice, this distance receives the important name of
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**margin** within SVM's theory. Therefore, the optimal separating hyperplane *maximizes* the margin
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of the training data.
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2014-11-28 21:21:28 +08:00
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![](images/optimal-hyperplane.png)
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How is the optimal hyperplane computed?
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---------------------------------------
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Let's introduce the notation used to define formally a hyperplane:
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\f[f(x) = \beta_{0} + \beta^{T} x,\f]
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where \f$\beta\f$ is known as the *weight vector* and \f$\beta_{0}\f$ as the *bias*.
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2020-03-21 08:25:49 +08:00
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@note A more in depth description of this and hyperplanes you can find in the section 4.5 (*Separating
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Hyperplanes*) of the book: *Elements of Statistical Learning* by T. Hastie, R. Tibshirani and J. H.
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Friedman (@cite HTF01).
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The optimal hyperplane can be represented in an infinite number of different ways by
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scaling of \f$\beta\f$ and \f$\beta_{0}\f$. As a matter of convention, among all the possible
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representations of the hyperplane, the one chosen is
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\f[|\beta_{0} + \beta^{T} x| = 1\f]
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where \f$x\f$ symbolizes the training examples closest to the hyperplane. In general, the training
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examples that are closest to the hyperplane are called **support vectors**. This representation is
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known as the **canonical hyperplane**.
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Now, we use the result of geometry that gives the distance between a point \f$x\f$ and a hyperplane
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\f$(\beta, \beta_{0})\f$:
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\f[\mathrm{distance} = \frac{|\beta_{0} + \beta^{T} x|}{||\beta||}.\f]
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In particular, for the canonical hyperplane, the numerator is equal to one and the distance to the
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support vectors is
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\f[\mathrm{distance}_{\text{ support vectors}} = \frac{|\beta_{0} + \beta^{T} x|}{||\beta||} = \frac{1}{||\beta||}.\f]
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Recall that the margin introduced in the previous section, here denoted as \f$M\f$, is twice the
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distance to the closest examples:
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\f[M = \frac{2}{||\beta||}\f]
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Finally, the problem of maximizing \f$M\f$ is equivalent to the problem of minimizing a function
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\f$L(\beta)\f$ subject to some constraints. The constraints model the requirement for the hyperplane to
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classify correctly all the training examples \f$x_{i}\f$. Formally,
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\f[\min_{\beta, \beta_{0}} L(\beta) = \frac{1}{2}||\beta||^{2} \text{ subject to } y_{i}(\beta^{T} x_{i} + \beta_{0}) \geq 1 \text{ } \forall i,\f]
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where \f$y_{i}\f$ represents each of the labels of the training examples.
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This is a problem of Lagrangian optimization that can be solved using Lagrange multipliers to obtain
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the weight vector \f$\beta\f$ and the bias \f$\beta_{0}\f$ of the optimal hyperplane.
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Source Code
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-----------
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2018-07-13 21:11:00 +08:00
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@add_toggle_cpp
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- **Downloadable code**: Click
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2021-12-22 21:01:26 +08:00
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[here](https://github.com/opencv/opencv/tree/4.x/samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp)
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- **Code at glance:**
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@include samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp
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@end_toggle
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@add_toggle_java
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- **Downloadable code**: Click
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2021-12-22 21:01:26 +08:00
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[here](https://github.com/opencv/opencv/tree/4.x/samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java)
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- **Code at glance:**
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@include samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java
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@end_toggle
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@add_toggle_python
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- **Downloadable code**: Click
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[here](https://github.com/opencv/opencv/tree/4.x/samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py)
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- **Code at glance:**
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@include samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py
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@end_toggle
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Explanation
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-----------
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2018-07-13 21:11:00 +08:00
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- **Set up the training data**
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The training data of this exercise is formed by a set of labeled 2D-points that belong to one of
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two different classes; one of the classes consists of one point and the other of three points.
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@add_toggle_cpp
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@snippet samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp setup1
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@end_toggle
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@add_toggle_java
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@snippet samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java setup1
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@end_toggle
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2018-07-13 21:11:00 +08:00
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@add_toggle_python
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@snippet samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py setup1
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@end_toggle
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The function @ref cv::ml::SVM::train that will be used afterwards requires the training data to be
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stored as @ref cv::Mat objects of floats. Therefore, we create these objects from the arrays
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defined above:
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@add_toggle_cpp
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@snippet samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp setup2
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@end_toggle
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2018-07-13 21:11:00 +08:00
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@add_toggle_java
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@snippet samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java setup2
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@end_toggle
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2018-07-13 21:11:00 +08:00
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@add_toggle_python
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@snippet samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py setup1
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@end_toggle
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- **Set up SVM's parameters**
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In this tutorial we have introduced the theory of SVMs in the most simple case, when the
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training examples are spread into two classes that are linearly separable. However, SVMs can be
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used in a wide variety of problems (e.g. problems with non-linearly separable data, a SVM using
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a kernel function to raise the dimensionality of the examples, etc). As a consequence of this,
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we have to define some parameters before training the SVM. These parameters are stored in an
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object of the class @ref cv::ml::SVM.
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2018-07-13 21:11:00 +08:00
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@add_toggle_cpp
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@snippet samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp init
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@end_toggle
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@add_toggle_java
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@snippet samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java init
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@end_toggle
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@add_toggle_python
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@snippet samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py init
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@end_toggle
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Here:
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- *Type of SVM*. We choose here the type @ref cv::ml::SVM::C_SVC "C_SVC" that can be used for
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n-class classification (n \f$\geq\f$ 2). The important feature of this type is that it deals
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with imperfect separation of classes (i.e. when the training data is non-linearly separable).
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This feature is not important here since the data is linearly separable and we chose this SVM
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type only for being the most commonly used.
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- *Type of SVM kernel*. We have not talked about kernel functions since they are not
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interesting for the training data we are dealing with. Nevertheless, let's explain briefly now
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the main idea behind a kernel function. It is a mapping done to the training data to improve
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its resemblance to a linearly separable set of data. This mapping consists of increasing the
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dimensionality of the data and is done efficiently using a kernel function. We choose here the
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type @ref cv::ml::SVM::LINEAR "LINEAR" which means that no mapping is done. This parameter is
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defined using cv::ml::SVM::setKernel.
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- *Termination criteria of the algorithm*. The SVM training procedure is implemented solving a
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constrained quadratic optimization problem in an **iterative** fashion. Here we specify a
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maximum number of iterations and a tolerance error so we allow the algorithm to finish in
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less number of steps even if the optimal hyperplane has not been computed yet. This
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parameter is defined in a structure @ref cv::TermCriteria .
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- **Train the SVM**
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We call the method @ref cv::ml::SVM::train to build the SVM model.
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2018-07-13 21:11:00 +08:00
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@add_toggle_cpp
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@snippet samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp train
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@end_toggle
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@add_toggle_java
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@snippet samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java train
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@end_toggle
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@add_toggle_python
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@snippet samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py train
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@end_toggle
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- **Regions classified by the SVM**
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The method @ref cv::ml::SVM::predict is used to classify an input sample using a trained SVM. In
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this example we have used this method in order to color the space depending on the prediction done
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by the SVM. In other words, an image is traversed interpreting its pixels as points of the
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Cartesian plane. Each of the points is colored depending on the class predicted by the SVM; in
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green if it is the class with label 1 and in blue if it is the class with label -1.
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@add_toggle_cpp
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@snippet samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp show
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@end_toggle
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@add_toggle_java
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@snippet samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java show
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@end_toggle
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@add_toggle_python
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@snippet samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py show
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@end_toggle
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- **Support vectors**
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We use here a couple of methods to obtain information about the support vectors.
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The method @ref cv::ml::SVM::getSupportVectors obtain all of the support
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vectors. We have used this methods here to find the training examples that are
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support vectors and highlight them.
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@add_toggle_cpp
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@snippet samples/cpp/tutorial_code/ml/introduction_to_svm/introduction_to_svm.cpp show_vectors
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@end_toggle
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@add_toggle_java
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@snippet samples/java/tutorial_code/ml/introduction_to_svm/IntroductionToSVMDemo.java show_vectors
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@end_toggle
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@add_toggle_python
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@snippet samples/python/tutorial_code/ml/introduction_to_svm/introduction_to_svm.py show_vectors
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@end_toggle
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Results
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-------
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- The code opens an image and shows the training examples of both classes. The points of one class
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are represented with white circles and black ones are used for the other class.
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- The SVM is trained and used to classify all the pixels of the image. This results in a division
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of the image in a blue region and a green region. The boundary between both regions is the
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optimal separating hyperplane.
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- Finally the support vectors are shown using gray rings around the training examples.
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2014-11-28 21:21:28 +08:00
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![](images/svm_intro_result.png)
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