采用鼠标事件,手动选择样本点,包括目标样本和背景样本。组成训练数据进行训练
1、主函数
#include "stdafx.h"
#include "opencv2/opencv.hpp"
using namespace cv;
using namespace cv::ml; Mat img,image;
Mat targetData, backData;
bool flag = true;
string wdname = "image"; void on_mouse(int event, int x, int y, int flags, void* ustc); //鼠标取样本点
void getTrainData(Mat &train_data, Mat &train_label); //生成训练数据
void svm(); //svm分类 int main(int argc, char** argv)
{
string path = "d:/peppers.png";
img = imread(path);
img.copyTo(image);
if (img.empty())
{
cout << "Image load error";
return ;
}
namedWindow(wdname);
setMouseCallback(wdname, on_mouse, ); for (;;)
{
imshow("image", img); int c = waitKey();
if ((c & ) == )
{
cout << "Exiting ...\n";
break;
}
if ((char)c == 'c')
{
flag = false;
}
if ((char)c == 'q')
{
destroyAllWindows();
break;
}
}
svm();
return ;
}
首先输入图像,调用setMouseCallback函数进行鼠标取点
2、鼠标事件
//鼠标在图像上取样本点,按q键退出
void on_mouse(int event, int x, int y, int flags, void* ustc)
{
if (event == CV_EVENT_LBUTTONDOWN)
{
Point pt = Point(x, y);
Vec3b point = img.at<Vec3b>(y, x); //取出该坐标处的像素值,注意x,y的顺序
Mat tmp = (Mat_<float>(, ) << point[], point[], point[]);
if (flag)
{
targetData.push_back(tmp); //加入正样本矩阵
circle(img, pt, , Scalar(, , ), -, ); //画圆,在图上显示点击的点 } else
{
backData.push_back(tmp); //加入负样本矩阵
circle(img, pt, , Scalar(, , ), -, ); }
imshow(wdname, img);
}
}
用鼠标在图像上点击,取出当前点的红绿蓝像素值进行训练。先选择任意个目标样本,然后按"c“键后选择任意个背景样本。样本数可以自己随意决定。样本选择完后,按”q"键完成样本选择。
3、svm分类
void getTrainData(Mat &train_data, Mat &train_label)
{
int m = targetData.rows;
int n = backData.rows;
cout << "正样本数::" << m << endl;
cout << "负样本数:" << n << endl;
vconcat(targetData, backData, train_data); //合并所有的样本点,作为训练数据
train_label = Mat(m + n, , CV_32S, Scalar::all()); //初始化标注
for (int i = m; i < m + n; i++)
train_label.at<int>(i, ) = -;
} void svm()
{
Mat train_data, train_label;
getTrainData(train_data, train_label); //获取鼠标选择的样本训练数据 // 设置参数
Ptr<SVM> svm = SVM::create();
svm->setType(SVM::C_SVC);
svm->setKernel(SVM::LINEAR); // 训练分类器
Ptr<TrainData> tData = TrainData::create(train_data, ROW_SAMPLE, train_label);
svm->train(tData); Vec3b color(, , );
// Show the decision regions given by the SVM
for (int i = ; i < image.rows; ++i)
for (int j = ; j < image.cols; ++j)
{
Vec3b point = img.at<Vec3b>(i, j); //取出该坐标处的像素值
Mat sampleMat = (Mat_<float>(, ) << point[], point[], point[]);
float response = svm->predict(sampleMat); //进行预测,返回1或-1,返回类型为float
if ((int)response != )
image.at<Vec3b>(i, j) = color; //将背景点设为黑色
} imshow("SVM Simple Example", image); // show it to the user
waitKey();
}
将正负样本矩阵,用vconcat合并成一个矩阵,用作训练分类器,并对相应的样本进行标注。最后将识别出的目标保留,将背景部分调成黑色。
4、完整程序
// svm.cpp : 定义控制台应用程序的入口点。
// #include "stdafx.h"
#include "opencv2/opencv.hpp"
using namespace cv;
using namespace cv::ml; Mat img,image;
Mat targetData, backData;
bool flag = true;
string wdname = "image"; void on_mouse(int event, int x, int y, int flags, void* ustc); //鼠标取样本点
void getTrainData(Mat &train_data, Mat &train_label); //生成训练数据
void svm(); //svm分类 int main(int argc, char** argv)
{
string path = "d:/peppers.png";
img = imread(path);
img.copyTo(image);
if (img.empty())
{
cout << "Image load error";
return ;
}
namedWindow(wdname);
setMouseCallback(wdname, on_mouse, ); for (;;)
{
imshow("image", img); int c = waitKey();
if ((c & ) == )
{
cout << "Exiting ...\n";
break;
}
if ((char)c == 'c')
{
flag = false;
}
if ((char)c == 'q')
{
destroyAllWindows();
break;
}
}
svm();
return ;
} //鼠标在图像上取样本点,按q键退出
void on_mouse(int event, int x, int y, int flags, void* ustc)
{
if (event == CV_EVENT_LBUTTONDOWN)
{
Point pt = Point(x, y);
Vec3b point = img.at<Vec3b>(y, x); //取出该坐标处的像素值,注意x,y的顺序
Mat tmp = (Mat_<float>(, ) << point[], point[], point[]);
if (flag)
{
targetData.push_back(tmp); //加入正样本矩阵
circle(img, pt, , Scalar(, , ), -, ); //画出点击的点 } else
{
backData.push_back(tmp); //加入负样本矩阵
circle(img, pt, , Scalar(, , ), -, ); }
imshow(wdname, img);
}
} void getTrainData(Mat &train_data, Mat &train_label)
{
int m = targetData.rows;
int n = backData.rows;
cout << "正样本数::" << m << endl;
cout << "负样本数:" << n << endl;
vconcat(targetData, backData, train_data); //合并所有的样本点,作为训练数据
train_label = Mat(m + n, , CV_32S, Scalar::all()); //初始化标注
for (int i = m; i < m + n; i++)
train_label.at<int>(i, ) = -;
} void svm()
{
Mat train_data, train_label;
getTrainData(train_data, train_label); //获取鼠标选择的样本训练数据 // 设置参数
Ptr<SVM> svm = SVM::create();
svm->setType(SVM::C_SVC);
svm->setKernel(SVM::LINEAR); // 训练分类器
Ptr<TrainData> tData = TrainData::create(train_data, ROW_SAMPLE, train_label);
svm->train(tData); Vec3b color(, , );
// Show the decision regions given by the SVM
for (int i = ; i < image.rows; ++i)
for (int j = ; j < image.cols; ++j)
{
Vec3b point = img.at<Vec3b>(i, j); //取出该坐标处的像素值
Mat sampleMat = (Mat_<float>(, ) << point[], point[], point[]);
float response = svm->predict(sampleMat); //进行预测,返回1或-1,返回类型为float
if ((int)response != )
image.at<Vec3b>(i, j) = color; //将背景设置为黑色
} imshow("SVM Simple Example", image);
waitKey();
}
输入原图像:
程序运行后显示:
