图像处理之拼接---图像拼接opencv

基于SURF特征的图像与视频拼接技术的研究和实现（一）

一直有计划研究实时图像拼接，但是直到最近拜读西电2013年张亚娟的《基于SURF特征的图像与视频拼接技术的研究和实现》，条理清晰、内容完整、实现的技术具有市场价值。因此定下决心以这篇论文为基础脉络，结合实际情况，进行“基于SURF特征的图像与视频拼接技术的研究和实现”。

一、基于opencv的surf实现

3.0以后，surf被分到了"opencv_contrib-master"中去，操作起来不习惯，这里仍然选择一直在使用的opencv2.48，其surf的调用方式为：

这里采用的是surffeaturedector的方法进行点的寻找，而后采用BFMatcher的方法进行数据比对。但这种方法错误的比较多，提供了FLANN的方法进行比对:

可以发现，除了错误一例，其他都是正确的。

继续来做，计算出单应矩阵

// raw_surf.cpp : 本例是对opencv-2.48相关例子的实现
//
#include "stdafx.h"
#include <iostream>
#include "opencv2/core/core.hpp"
#include "opencv2/features2d/features2d.hpp"
#include "opencv2/highgui/highgui.hpp"
#include "opencv2/nonfree/features2d.hpp"
#include "opencv2/calib3d/calib3d.hpp"
using namespace std;
using namespace cv;
int main( int argc, char** argv )
{

    Mat img_1 = imread( "img_opencv_1.png", 0 );
    Mat img_2 = imread( "img_opencv_2.png", 0 );
    if( !img_1.data || !img_2.data )
    { std::cout<< " --(!) Error reading images " << std::endl; return -1; }
    //-- Step 1: Detect the keypoints using SURF Detector
    int minHessian = 400;
    SurfFeatureDetector detector( minHessian );
    std::vector<KeyPoint> keypoints_1, keypoints_2;
    detector.detect( img_1, keypoints_1 );
    detector.detect( img_2, keypoints_2 );
    //-- Draw keypoints
    Mat img_keypoints_1; Mat img_keypoints_2;
    drawKeypoints( img_1, keypoints_1, img_keypoints_1, Scalar::all(-1), DrawMatchesFlags::DEFAULT );
    drawKeypoints( img_2, keypoints_2, img_keypoints_2, Scalar::all(-1), DrawMatchesFlags::DEFAULT );
    //-- Step 2: Calculate descriptors (feature vectors)
    SurfDescriptorExtractor extractor;
    Mat descriptors_1, descriptors_2;
    extractor.compute( img_1, keypoints_1, descriptors_1 );
    extractor.compute( img_2, keypoints_2, descriptors_2 );
    //-- Step 3: Matching descriptor vectors using FLANN matcher
    FlannBasedMatcher matcher;
    std::vector< DMatch > matches;
    matcher.match( descriptors_1, descriptors_2, matches );
    double max_dist = 0; double min_dist = 100;
    //-- Quick calculation of max and min distances between keypoints
    for( int i = 0; i < descriptors_1.rows; i++ )
    { double dist = matches[i].distance;
    if( dist < min_dist ) min_dist = dist;
    if( dist > max_dist ) max_dist = dist;
    }
    printf("-- Max dist : %f \n", max_dist );
    printf("-- Min dist : %f \n", min_dist );
    //-- Draw only "good" matches (i.e. whose distance is less than 2*min_dist,
    //-- or a small arbitary value ( 0.02 ) in the event that min_dist is very
    //-- small)
    //-- PS.- radiusMatch can also be used here.
    std::vector< DMatch > good_matches;
    for( int i = 0; i < descriptors_1.rows; i++ )
    { if( matches[i].distance <= /*max(2*min_dist, 0.02)*/3*min_dist )
    { good_matches.push_back( matches[i]); }
    }
    //-- Draw only "good" matches
    Mat img_matches;
    drawMatches( img_1, keypoints_1, img_2, keypoints_2,
        good_matches, img_matches, Scalar::all(-1), Scalar::all(-1),
        vector<char>(), DrawMatchesFlags::NOT_DRAW_SINGLE_POINTS );
    //-- Localize the object from img_1 in img_2
    std::vector<Point2f> obj;
    std::vector<Point2f> scene;
    for( int i = 0; i < (int)good_matches.size(); i++ )
    {
        obj.push_back( keypoints_1[ good_matches[i].queryIdx ].pt );
        scene.push_back( keypoints_2[ good_matches[i].trainIdx ].pt );
        printf( "-- Good Match [%d] Keypoint 1: %d  -- Keypoint 2: %d  \n", i, good_matches[i].queryIdx, good_matches[i].trainIdx );
    }
    //直接调用ransac
    Mat H = findHomography( obj, scene, CV_RANSAC );
    //-- Get the corners from the image_1 ( the object to be "detected" )
    std::vector<Point2f> obj_corners(4);
    obj_corners[0] = Point(0,0); obj_corners[1] = Point( img_1.cols, 0 );
    obj_corners[2] = Point( img_1.cols, img_1.rows ); obj_corners[3] = Point( 0, img_1.rows );
    std::vector<Point2f> scene_corners(4);
    perspectiveTransform( obj_corners, scene_corners, H);
    //-- Draw lines between the corners (the mapped object in the scene - image_2 )
    Point2f offset( (float)img_1.cols, 0);
    line( img_matches, scene_corners[0] + offset, scene_corners[1] + offset, Scalar(0, 255, 0), 4 );
    line( img_matches, scene_corners[1] + offset, scene_corners[2] + offset, Scalar( 0, 255, 0), 4 );
    line( img_matches, scene_corners[2] + offset, scene_corners[3] + offset, Scalar( 0, 255, 0), 4 );
    line( img_matches, scene_corners[3] + offset, scene_corners[0] + offset, Scalar( 0, 255, 0), 4 );
    //-- Show detected matches
    imshow( "Good Matches & Object detection", img_matches );
    waitKey(0);
    return 0;
}

简化后和注释后的版本

// raw_surf.cpp : 本例是对opencv-2.48相关例子的实现

#include "stdafx.h"

#include <iostream>

#include "opencv2/core/core.hpp"

#include "opencv2/features2d/features2d.hpp"

#include "opencv2/highgui/highgui.hpp"

#include "opencv2/nonfree/features2d.hpp"

#include "opencv2/calib3d/calib3d.hpp"

using namespace std;

using namespace cv;

int main( int argc, char** argv )

{

Mat img_1 = imread( "img_opencv_1.png", 0 );

Mat img_2 = imread( "img_opencv_2.png", 0 );

if( !img_1.data || !img_2.data )

{ std::cout<< " --(!) Error reading images " << std::endl; return -1; }

//-- Step 1: 使用SURF识别出特征点

int minHessian = 400;

SurfFeatureDetector detector( minHessian );

std::vector<KeyPoint> keypoints_1, keypoints_2;

detector.detect( img_1, keypoints_1 );

detector.detect( img_2, keypoints_2 );

//-- Step 2: 描述SURF特征

SurfDescriptorExtractor extractor;

Mat descriptors_1, descriptors_2;

extractor.compute( img_1, keypoints_1, descriptors_1 );

extractor.compute( img_2, keypoints_2, descriptors_2 );

//-- Step 3: 匹配

FlannBasedMatcher matcher;//BFMatcher为强制匹配

std::vector< DMatch > matches;

matcher.match( descriptors_1, descriptors_2, matches );

//取最大最小距离

double max_dist = 0; double min_dist = 100;

for( int i = 0; i < descriptors_1.rows; i++ )

{

double dist = matches[i].distance;

if( dist < min_dist ) min_dist = dist;

if( dist > max_dist ) max_dist = dist;

}

std::vector< DMatch > good_matches;

for( int i = 0; i < descriptors_1.rows; i++ )

{

if( matches[i].distance <= 3*min_dist )//这里的阈值选择了3倍的min_dist

{

good_matches.push_back( matches[i]);

}

//画出"good match"

Mat img_matches;

drawMatches( img_1, keypoints_1, img_2, keypoints_2,

good_matches, img_matches, Scalar::all(-1), Scalar::all(-1),

vector<char>(), DrawMatchesFlags::NOT_DRAW_SINGLE_POINTS );

//-- Localize the object from img_1 in img_2

std::vector<Point2f> obj;

std::vector<Point2f> scene;

for( int i = 0; i < (int)good_matches.size(); i++ )

{

obj.push_back( keypoints_1[ good_matches[i].queryIdx ].pt );

scene.push_back( keypoints_2[ good_matches[i].trainIdx ].pt );

}

//直接调用ransac,计算单应矩阵

Mat H = findHomography( obj, scene, CV_RANSAC );

//-- Get the corners from the image_1 ( the object to be "detected" )

std::vector<Point2f> obj_corners(4);

obj_corners[0] = Point(0,0);

obj_corners[1] = Point( img_1.cols, 0 );

obj_corners[2] = Point( img_1.cols, img_1.rows );

obj_corners[3] = Point( 0, img_1.rows );

std::vector<Point2f> scene_corners(4);

perspectiveTransform( obj_corners, scene_corners, H);

//-- Draw lines between the corners (the mapped object in the scene - image_2 )

Point2f offset( (float)img_1.cols, 0);

line( img_matches, scene_corners[0] + offset, scene_corners[1] + offset, Scalar(0, 255, 0), 4 );

line( img_matches, scene_corners[1] + offset, scene_corners[2] + offset, Scalar( 0, 255, 0), 4 );

line( img_matches, scene_corners[2] + offset, scene_corners[3] + offset, Scalar( 0, 255, 0), 4 );

line( img_matches, scene_corners[3] + offset, scene_corners[0] + offset, Scalar( 0, 255, 0), 4 );

//-- Show detected matches

imshow( "Good Matches & Object detection", img_matches );

waitKey(0);

return 0;

}

这里有两点需要注意，一个是除了FlannBasedMatcher之外，还有一种mathcer叫做BFMatcher,后者为强制匹配.

此外计算所谓GOODFEATURE的时候，采用了 3*min_dist的方法，我认为这里和论文中指出的“误差阈值设为3”是一致的，如果理解错误请指出，感谢！

同时测试了航拍图片和连铸图片,航拍图片是自然图片，特征丰富；

连铸图片由于表面干扰大于原始纹理，无法得到单应矩阵

最后，添加计算RANSAC内点外点的相关代码，这里以3作为分界线

// raw_surf.cpp : 本例是对opencv-2.48相关例子的实现

//
#include "stdafx.h"
#include <iostream>
#include "opencv2/core/core.hpp"
#include "opencv2/imgproc/imgproc.hpp"
#include "opencv2/features2d/features2d.hpp"
#include "opencv2/highgui/highgui.hpp"
#include "opencv2/nonfree/features2d.hpp"
#include "opencv2/calib3d/calib3d.hpp"
using namespace std;
using namespace cv;
//获得两个pointf之间的距离
float fDistance(Point2f p1,Point2f p2)
{
    float ftmp = (p1.x-p2.x)*(p1.x-p2.x) + (p1.y-p2.y)*(p1.y-p2.y);
    ftmp = sqrt((float)ftmp);
    return ftmp;
}
int main( int argc, char** argv )
{
    Mat img_1 = imread( "img_opencv_1.png", 0 );
    Mat img_2 = imread( "img_opencv_2.png", 0 );
    ////添加于连铸图像
    //img_1 = img_1(Rect(20,0,img_1.cols-40,img_1.rows));
    //img_2 = img_2(Rect(20,0,img_1.cols-40,img_1.rows));
//    cv::Canny(img_1,img_1,100,200);
//    cv::Canny(img_2,img_2,100,200);
    if( !img_1.data || !img_2.data )
    { std::cout<< " --(!) Error reading images " << std::endl; return -1; }
    //-- Step 1: 使用SURF识别出特征点
    int minHessian = 400;
    SurfFeatureDetector detector( minHessian );
    std::vector<KeyPoint> keypoints_1, keypoints_2;
    detector.detect( img_1, keypoints_1 );
    detector.detect( img_2, keypoints_2 );
    //-- Step 2: 描述SURF特征
    SurfDescriptorExtractor extractor;
    Mat descriptors_1, descriptors_2;
    extractor.compute( img_1, keypoints_1, descriptors_1 );
    extractor.compute( img_2, keypoints_2, descriptors_2 );
    //-- Step 3: 匹配
    FlannBasedMatcher matcher;//BFMatcher为强制匹配
    std::vector< DMatch > matches;
    matcher.match( descriptors_1, descriptors_2, matches );
    //取最大最小距离
    double max_dist = 0; double min_dist = 100;
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        double dist = matches[i].distance;
        if( dist < min_dist ) min_dist = dist;
        if( dist > max_dist ) max_dist = dist;
    }
    std::vector< DMatch > good_matches;
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        if( matches[i].distance <= 3*min_dist )//这里的阈值选择了3倍的min_dist
            {
                good_matches.push_back( matches[i]);
             }
    }
    //画出"good match"
    Mat img_matches;
    drawMatches( img_1, keypoints_1, img_2, keypoints_2,
        good_matches, img_matches, Scalar::all(-1), Scalar::all(-1),
        vector<char>(), DrawMatchesFlags::NOT_DRAW_SINGLE_POINTS );
    //-- Localize the object from img_1 in img_2
    std::vector<Point2f> obj;
    std::vector<Point2f> scene;
    for( int i = 0; i < (int)good_matches.size(); i++ )
    {
        obj.push_back( keypoints_1[ good_matches[i].queryIdx ].pt );
        scene.push_back( keypoints_2[ good_matches[i].trainIdx ].pt );
    }
    //直接调用ransac,计算单应矩阵
    Mat H = findHomography( obj, scene, CV_RANSAC );
    //-- Get the corners from the image_1 ( the object to be "detected" )
    std::vector<Point2f> obj_corners(4);
    obj_corners[0] = Point(0,0);
    obj_corners[1] = Point( img_1.cols, 0 );
    obj_corners[2] = Point( img_1.cols, img_1.rows );
    obj_corners[3] = Point( 0, img_1.rows );
    std::vector<Point2f> scene_corners(4);
    perspectiveTransform( obj_corners, scene_corners, H);
    //计算内点外点
    std::vector<Point2f> scene_test(obj.size());
    perspectiveTransform(obj,scene_test,H);
    for (int i=0;i<scene_test.size();i++)
    {
       printf("%d is %f \n",i+1,fDistance(scene[i],scene_test[i]));
    }

    //-- Draw lines between the corners (the mapped object in the scene - image_2 )
    Point2f offset( (float)img_1.cols, 0);
    line( img_matches, scene_corners[0] + offset, scene_corners[1] + offset, Scalar(0, 255, 0), 4 );
    line( img_matches, scene_corners[1] + offset, scene_corners[2] + offset, Scalar( 0, 255, 0), 4 );
    line( img_matches, scene_corners[2] + offset, scene_corners[3] + offset, Scalar( 0, 255, 0), 4 );
    line( img_matches, scene_corners[3] + offset, scene_corners[0] + offset, Scalar( 0, 255, 0), 4 );
    //-- Show detected matches
    imshow( "Good Matches & Object detection", img_matches );
    waitKey(0);
    return 0;
}

结果显示

其中，有误差的点就很明显了。

小结一下，这里实现了使用opencv得到两幅图像之间的单应矩阵的方法。不是所有的图像都能够获得单应矩阵的，必须是两幅本身就有关系的图片才可以；而且最好是自然图像，像生产线上的这种图像，其拼接就需要采用其他方法。

二、拼接和融合

由于之前已经计算出了“单应矩阵”，所以这里直接利用这个矩阵就好。需要注意的一点是理清楚“帧”和拼接图像之间的关系。一般来说，我们采用的是“柱面坐标”或平面坐标。书中采用的是若干图像在水平方向上基本上是一字排开，是平面坐标。那么，如果按照文中的“帧到拼接图像”的方法，我们认为图像拼接的顺序就是由左到右，一幅一幅地计算误差，而后进行叠加。

为了方便说明算法，采用了《学习opencv》中提供的教堂图像

其结果就是经过surf匹配，而将右边的图像形变成为适合叠加的状态。

基于此，进行图像对准

依据论文中提到的3种方法进行融合

// raw_surf.cpp : 本例是对opencv-2.48相关例子的实现
//
#include "stdafx.h"
#include <iostream>
#include "opencv2/core/core.hpp"
#include "opencv2/imgproc/imgproc.hpp"
#include "opencv2/features2d/features2d.hpp"
#include "opencv2/highgui/highgui.hpp"
#include "opencv2/nonfree/features2d.hpp"
#include "opencv2/calib3d/calib3d.hpp"
using namespace std;
using namespace cv;
int main( int argc, char** argv )
{

    Mat img_1 ;
    Mat img_2 ;
    Mat img_raw_1 = imread("c1.bmp");
    Mat img_raw_2 = imread("c3.bmp");
    cvtColor(img_raw_1,img_1,CV_BGR2GRAY);
    cvtColor(img_raw_2,img_2,CV_BGR2GRAY);
    //-- Step 1: 使用SURF识别出特征点
    int minHessian = 400;
    SurfFeatureDetector detector( minHessian );
    std::vector<KeyPoint> keypoints_1, keypoints_2;
    detector.detect( img_1, keypoints_1 );
    detector.detect( img_2, keypoints_2 );
    //-- Step 2: 描述SURF特征
    SurfDescriptorExtractor extractor;
    Mat descriptors_1, descriptors_2;
    extractor.compute( img_1, keypoints_1, descriptors_1 );
    extractor.compute( img_2, keypoints_2, descriptors_2 );
    //-- Step 3: 匹配
    FlannBasedMatcher matcher;//BFMatcher为强制匹配
    std::vector< DMatch > matches;
    matcher.match( descriptors_1, descriptors_2, matches );
    //取最大最小距离
    double max_dist = 0; double min_dist = 100;
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        double dist = matches[i].distance;
        if( dist < min_dist ) min_dist = dist;
        if( dist > max_dist ) max_dist = dist;
    }
    std::vector< DMatch > good_matches;
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        if( matches[i].distance <= 3*min_dist )//这里的阈值选择了3倍的min_dist
        {
            good_matches.push_back( matches[i]);
        }
    }
    //-- Localize the object from img_1 in img_2
    std::vector<Point2f> obj;
    std::vector<Point2f> scene;
    for( int i = 0; i < (int)good_matches.size(); i++ )
    {
        //这里采用“帧向拼接图像中添加的方法”，因此左边的是scene,右边的是obj
        scene.push_back( keypoints_1[ good_matches[i].queryIdx ].pt );
        obj.push_back( keypoints_2[ good_matches[i].trainIdx ].pt );
    }
    //直接调用ransac,计算单应矩阵
    Mat H = findHomography( obj, scene, CV_RANSAC );
    //图像对准
    Mat result;
    Mat resultback; //保存的是新帧经过单应矩阵变换以后的图像
    warpPerspective(img_raw_2,result,H,Size(2*img_2.cols,img_2.rows));
    result.copyTo(resultback);
    Mat half(result,cv::Rect(0,0,img_2.cols,img_2.rows));
    img_raw_1.copyTo(half);
    imshow("ajust",result);
    //渐入渐出融合
    Mat result_linerblend = result.clone();
     double dblend = 0.0;
     int ioffset =img_2.cols-100;
     for (int i = 0;i<100;i++)
     {
         result_linerblend.col(ioffset+i) = result.col(ioffset+i)*(1-dblend) + resultback.col(ioffset+i)*dblend;
         dblend = dblend +0.01;
    }
    imshow("result_linerblend",result_linerblend);
    //最大值法融合
    Mat result_maxvalue = result.clone();
    for (int i = 0;i<img_2.rows;i++)
    {
        for (int j=0;j<100;j++)
        {
            int iresult= result.at<Vec3b>(i,ioffset+j)[0]+ result.at<Vec3b>(i,ioffset+j)[1]+ result.at<Vec3b>(i,ioffset+j)[2];
            int iresultback = resultback.at<Vec3b>(i,ioffset+j)[0]+ resultback.at<Vec3b>(i,ioffset+j)[1]+ resultback.at<Vec3b>(i,ioffset+j)[2];
            if (iresultback >iresult)
            {
                result_maxvalue.at<Vec3b>(i,ioffset+j) = resultback.at<Vec3b>(i,ioffset+j);
            }
        }
    }
    imshow("result_maxvalue",result_maxvalue);
    //带阈值的加权平滑处理
    Mat result_advance = result.clone();
    for (int i = 0;i<img_2.rows;i++)
    {
        for (int j = 0;j<33;j++)
        {
            int iimg1= result.at<Vec3b>(i,ioffset+j)[0]+ result.at<Vec3b>(i,ioffset+j)[1]+ result.at<Vec3b>(i,ioffset+j)[2];
            //int iimg2= resultback.at<Vec3b>(i,ioffset+j)[0]+ resultback.at<Vec3b>(i,ioffset+j)[1]+ resultback.at<Vec3b>(i,ioffset+j)[2];
            int ilinerblend = result_linerblend.at<Vec3b>(i,ioffset+j)[0]+ result_linerblend.at<Vec3b>(i,ioffset+j)[1]+ result_linerblend.at<Vec3b>(i,ioffset+j)[2];
            if (abs(iimg1 - ilinerblend)<3)
            {
                result_advance.at<Vec3b>(i,ioffset+j) = result_linerblend.at<Vec3b>(i,ioffset+j);
            }
        }
    }
    for (int i = 0;i<img_2.rows;i++)
    {
        for (int j = 33;j<66;j++)
        {
            int iimg1= result.at<Vec3b>(i,ioffset+j)[0]+ result.at<Vec3b>(i,ioffset+j)[1]+ result.at<Vec3b>(i,ioffset+j)[2];
            int iimg2= resultback.at<Vec3b>(i,ioffset+j)[0]+ resultback.at<Vec3b>(i,ioffset+j)[1]+ resultback.at<Vec3b>(i,ioffset+j)[2];
            int ilinerblend = result_linerblend.at<Vec3b>(i,ioffset+j)[0]+ result_linerblend.at<Vec3b>(i,ioffset+j)[1]+ result_linerblend.at<Vec3b>(i,ioffset+j)[2];
            if (abs(max(iimg1,iimg2) - ilinerblend)<3)
            {
                result_advance.at<Vec3b>(i,ioffset+j) = result_linerblend.at<Vec3b>(i,ioffset+j);
            }
            else if (iimg2>iimg1)
            {
                result_advance.at<Vec3b>(i,ioffset+j) = resultback.at<Vec3b>(i,ioffset+j);
            }
        }
    }
    for (int i = 0;i<img_2.rows;i++)
    {
        for (int j = 66;j<100;j++)
        {
            //int iimg1= result.at<Vec3b>(i,ioffset+j)[0]+ result.at<Vec3b>(i,ioffset+j)[1]+ result.at<Vec3b>(i,ioffset+j)[2];
            int iimg2= resultback.at<Vec3b>(i,ioffset+j)[0]+ resultback.at<Vec3b>(i,ioffset+j)[1]+ resultback.at<Vec3b>(i,ioffset+j)[2];
            int ilinerblend = result_linerblend.at<Vec3b>(i,ioffset+j)[0]+ result_linerblend.at<Vec3b>(i,ioffset+j)[1]+ result_linerblend.at<Vec3b>(i,ioffset+j)[2];
            if (abs(iimg2 - ilinerblend)<3)
            {
                result_advance.at<Vec3b>(i,ioffset+j) = result_linerblend.at<Vec3b>(i,ioffset+j);
            }
            else
            {
                result_advance.at<Vec3b>(i,ioffset+j) = resultback.at<Vec3b>(i,ioffset+j);
            }
        }
    }
    imshow("result_advance",result_advance);
    waitKey(0);
    return 0;
}

目前看来，maxvalue是最好的融合方法，但是和论文中提到的一样，此类图片不能很好地体现融合算法的特点，为此我也拍摄了和论文中类似的图片。发现想拍摄质量较好的图片，还是需要一定的硬件和技巧的。因此，软件和硬件，在使用的过程中应该结合起来。

此外，使用文中图片，效果如下

换一组图片，可以发现不同的结果

相比较而言，还是linerblend能够保持不错的质量，而具体到底采取哪种拼接的方式，必须根据实际情况来选择。

三、多图连续融合拼接

前面处理的是2图的例子，至少将这种情况推广到3图，这样才能够得到统一处理的经验。

连续图像处理，不仅仅是在已经处理好的图像上面再添加一幅图，其中比较关键的一点就是如何来处理已经拼接好的图像。

那么，m2也就是H.at<char>(0,2)就是水平位移。但是在实际使用中，始终无法正确取得这个值

Mat outImage =H.clone();
    uchar* outData=outImage.ptr<uchar>(0);
    int itemp = outData[2];     //获得偏移
    line(result_linerblend,Point(result_linerblend.cols-itemp,0),Point(result_linerblend.cols-itemp,img_2.rows),Scalar(255,255,255),2);
    imshow("result_linerblend",result_linerblend);

只好采取编写专门代码的方法进行处理

//获取已经处理图像的边界
    Mat matmask = result_linerblend.clone();
    int idaterow0 = 0;int idaterowend = 0;//标识了最上面和最小面第一个不为0的树，这里采用的是宽度减去的算法
    for(int j=matmask.cols-1;j>=0;j--)
    {
        if (matmask.at<Vec3b>(0,j)[0]>0)
        {
            idaterow0 = j;
            break;
        }
    }
     for(int j=matmask.cols-1;j>=0;j--)
    {
        if (matmask.at<Vec3b>(matmask.rows-1,j)[0]>0)
        {
            idaterowend = j;
            break;
        }
    }

    line(matmask,Point(min(idaterow0,idaterowend),0),Point(min(idaterow0,idaterowend),img_2.rows),Scalar(255,255,255),2);
    imshow("result_linerblend",matmask);

效果良好稳定.目前的实现是将白线以左的区域切割下来进行拼接。

基于此，编写3图拼接，效果如下。目前的图像质量，在差值上面可能还需要增强，下一步处理

// blend_series.cpp : 多图拼接
//
#include "stdafx.h"
#include <iostream>
#include "opencv2/core/core.hpp"
#include "opencv2/imgproc/imgproc.hpp"
#include "opencv2/features2d/features2d.hpp"
#include "opencv2/highgui/highgui.hpp"
#include "opencv2/nonfree/features2d.hpp"
#include "opencv2/calib3d/calib3d.hpp"
using namespace std;
using namespace cv;
int main( int argc, char** argv )
{
    Mat img_1 ;
    Mat img_2 ;
    Mat img_raw_1 = imread("Univ3.jpg");
    Mat img_raw_2 = imread("Univ2.jpg");
    cvtColor(img_raw_1,img_1,CV_BGR2GRAY);
    cvtColor(img_raw_2,img_2,CV_BGR2GRAY);
    //-- Step 1: 使用SURF识别出特征点
    int minHessian = 400;
    SurfFeatureDetector detector( minHessian );
    std::vector<KeyPoint> keypoints_1, keypoints_2;
    detector.detect( img_1, keypoints_1 );
    detector.detect( img_2, keypoints_2 );
    //-- Step 2: 描述SURF特征
    SurfDescriptorExtractor extractor;
    Mat descriptors_1, descriptors_2;
    extractor.compute( img_1, keypoints_1, descriptors_1 );
    extractor.compute( img_2, keypoints_2, descriptors_2 );
    //-- Step 3: 匹配
    FlannBasedMatcher matcher;//BFMatcher为强制匹配
    std::vector< DMatch > matches;
    matcher.match( descriptors_1, descriptors_2, matches );
    //取最大最小距离
    double max_dist = 0; double min_dist = 100;
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        double dist = matches[i].distance;
        if( dist < min_dist ) min_dist = dist;
        if( dist > max_dist ) max_dist = dist;
    }
    std::vector< DMatch > good_matches;
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        if( matches[i].distance <= 3*min_dist )//这里的阈值选择了3倍的min_dist
        {
            good_matches.push_back( matches[i]);
        }
    }
    //-- Localize the object from img_1 in img_2
    std::vector<Point2f> obj;
    std::vector<Point2f> scene;
    for( int i = 0; i < (int)good_matches.size(); i++ )
    {
        //这里采用“帧向拼接图像中添加的方法”，因此左边的是scene,右边的是obj
        scene.push_back( keypoints_1[ good_matches[i].queryIdx ].pt );
        obj.push_back( keypoints_2[ good_matches[i].trainIdx ].pt );
    }
    //直接调用ransac,计算单应矩阵
    Mat H = findHomography( obj, scene, CV_RANSAC );
    //图像对准
    Mat result;
    Mat resultback; //保存的是新帧经过单应矩阵变换以后的图像
    warpPerspective(img_raw_2,result,H,Size(2*img_2.cols,img_2.rows));
    result.copyTo(resultback);
    Mat half(result,cv::Rect(0,0,img_2.cols,img_2.rows));
    img_raw_1.copyTo(half);
    //imshow("ajust",result);
    //渐入渐出融合
    Mat result_linerblend = result.clone();
    double dblend = 0.0;
    int ioffset =img_2.cols-100;
    for (int i = 0;i<100;i++)
    {
        result_linerblend.col(ioffset+i) = result.col(ioffset+i)*(1-dblend) + resultback.col(ioffset+i)*dblend;
        dblend = dblend +0.01;
    }
    //获取已经处理图像的边界
    Mat matmask = result_linerblend.clone();
    int idaterow0 = 0;int idaterowend = 0;//标识了最上面和最小面第一个不为0的树，这里采用的是宽度减去的算法
    for(int j=matmask.cols-1;j>=0;j--)
    {
        if (matmask.at<Vec3b>(0,j)[0]>0)
        {
            idaterow0 = j;
            break;
        }
    }
     for(int j=matmask.cols-1;j>=0;j--)
    {
        if (matmask.at<Vec3b>(matmask.rows-1,j)[0]>0)
        {
            idaterowend = j;
            break;
        }
    }

    line(matmask,Point(min(idaterow0,idaterowend),0),Point(min(idaterow0,idaterowend),img_2.rows),Scalar(255,255,255),2);
    imshow("result_linerblend",matmask);
    /////////////////---------------对结果图像继续处理---------------------------------/////////////////
    img_raw_1 = result_linerblend(Rect(0,0,min(idaterow0,idaterowend),img_2.rows));
    img_raw_2 = imread("Univ1.jpg");
    cvtColor(img_raw_1,img_1,CV_BGR2GRAY);
    cvtColor(img_raw_2,img_2,CV_BGR2GRAY);
    ////-- Step 1: 使用SURF识别出特征点
    //
    SurfFeatureDetector detector2( minHessian );
    keypoints_1.clear();
    keypoints_2.clear();
    detector2.detect( img_1, keypoints_1 );
    detector2.detect( img_2, keypoints_2 );
    //-- Step 2: 描述SURF特征
    SurfDescriptorExtractor extractor2;
    extractor2.compute( img_1, keypoints_1, descriptors_1 );
    extractor2.compute( img_2, keypoints_2, descriptors_2 );
    //-- Step 3: 匹配
    FlannBasedMatcher matcher2;//BFMatcher为强制匹配
    matcher2.match( descriptors_1, descriptors_2, matches );
    //取最大最小距离
     max_dist = 0;  min_dist = 100;
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        double dist = matches[i].distance;
        if( dist < min_dist ) min_dist = dist;
        if( dist > max_dist ) max_dist = dist;
    }
    good_matches.clear();
    for( int i = 0; i < descriptors_1.rows; i++ )
    {
        if( matches[i].distance <= 3*min_dist )//这里的阈值选择了3倍的min_dist
        {
            good_matches.push_back( matches[i]);
        }
    }
    //-- Localize the object from img_1 in img_2
    obj.clear();
    scene.clear();
    for( int i = 0; i < (int)good_matches.size(); i++ )
    {
        //这里采用“帧向拼接图像中添加的方法”，因此左边的是scene,右边的是obj
        scene.push_back( keypoints_1[ good_matches[i].queryIdx ].pt );
        obj.push_back( keypoints_2[ good_matches[i].trainIdx ].pt );
    }
    //直接调用ransac,计算单应矩阵
     H = findHomography( obj, scene, CV_RANSAC );
    //图像对准
    warpPerspective(img_raw_2,result,H,Size(img_1.cols+img_2.cols,img_2.rows));
    result.copyTo(resultback);
    Mat half2(result,cv::Rect(0,0,img_1.cols,img_1.rows));
    img_raw_1.copyTo(half2);
    imshow("ajust",result);
    //渐入渐出融合
    result_linerblend = result.clone();
     dblend = 0.0;
     ioffset =img_1.cols-100;
    for (int i = 0;i<100;i++)
    {
        result_linerblend.col(ioffset+i) = result.col(ioffset+i)*(1-dblend) + resultback.col(ioffset+i)*dblend;
        dblend = dblend +0.01;
    }
    imshow("result_linerblend",result_linerblend);
    waitKey(0);
    return 0;
}

复制粘贴，实现5图拼接。这个时候发现，3图往往是一个极限值（这也可能就是为什么opencv里面的例子提供的是3图），当第四图出现的时候，其单应效果非常差

为什么会出现这种情况，反思后认识到，论文中采用的是平面坐标，也就是所有的图片都是基本位于一个平面上的，这一点特别通过她后面的那个罗技摄像头的部署能够看出来。但是在现实中，更常见的情况是人站在中间，360度地拍摄，这个时候需要采用柱面坐标系，也就是一开始对于图像要进行相关处理，也就是所谓的柱状投影。

可以得到这样的效果，这个效果是否正确还有待商榷，但是基于此的确可以更进一步地做东西了。

// column_transoform.cpp : 桶装投影
//
#include "stdafx.h"
#include <iostream>
#include "opencv2/core/core.hpp"
#include "opencv2/imgproc/imgproc.hpp"
#include "opencv2/features2d/features2d.hpp"
#include "opencv2/highgui/highgui.hpp"
#include "opencv2/nonfree/features2d.hpp"
#include "opencv2/calib3d/calib3d.hpp"
using namespace std;
using namespace cv;
#define  PI 3.14159

int main( int argc, char** argv )
{
    Mat img_1 = imread( "Univ1.jpg");
    Mat img_result = img_1.clone();
    for(int i=0;i<img_result.rows;i++)
    {        for(int j=0;j<img_result.cols;j++)
        {
            img_result.at<Vec3b>(i,j)=0;
        }
    }

    int W = img_1.cols;
    int H = img_1.rows;
    float r = W/(2*tan(PI/6));
    float k = 0;
    float fx=0;
    float fy=0;
    for(int i=0;i<img_1.rows;i++)
    {        for(int j=0;j<img_1.cols;j++)
        {
            k = sqrt((float)(r*r+(W/2-j)*(W/2-j)));
            fx = r*sin(PI/6)+r*sin(atan((j -W/2 )/r));
            fy = H/2 +r*(i-H/2)/k;
            int ix = (int)fx;
            int iy = (int)fy;
            if (ix<W&&ix>=0&&iy<H&&iy>=0)
            {
                img_result.at<Vec3b>(iy,ix)= img_1.at<Vec3b>(i,j);

            }

        }
    }

    imshow( "桶状投影", img_1 );
    imshow("img_result",img_result);
    waitKey(0);
    return 0;
}

效果依然是不佳，看来在这个地方，不仅仅是做一个桶形变换那么简单，一定有定量的参数在里面，也可能是我的变换写错了。这个下一步研究。

【未完待续】

http://www.cnblogs.com/jsxyhelu/p/4475809.html

http://blog.csdn.net/jh19871985/article/details/8477935

posted @ 2015-03-17 12:08 midu 阅读(13385) 评论(6) 编辑收藏举报

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图像处理之拼接---图像拼接opencv

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