opencv 中 快速傅里叶变换 FFT
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opencv 中 傅里叶变换 FFT,代码如下:
void fft2(IplImage *src, IplImage *dst){ //实部、虚部IplImage *image_Re = 0, *image_Im = 0, *Fourier = 0;// int i, j;image_Re = cvCreateImage(cvGetSize(src), IPL_DEPTH_64F, 1); //实部//Imaginary partimage_Im = cvCreateImage(cvGetSize(src), IPL_DEPTH_64F, 1); //虚部//2 channels (image_Re, image_Im)Fourier = cvCreateImage(cvGetSize(src), IPL_DEPTH_64F, 2);// Real part conversion from u8 to 64f (double)cvConvertScale(src, image_Re);// Imaginary part (zeros)cvZero(image_Im);// Join real and imaginary parts and stock them in Fourier imagecvMerge(image_Re, image_Im, 0, 0, Fourier);// Application of the forward Fourier transformcvDFT(Fourier, dst, CV_DXT_FORWARD);cvReleaseImage(&image_Re);cvReleaseImage(&image_Im);cvReleaseImage(&Fourier);}void fft2shift(IplImage *src, IplImage *dst){IplImage *image_Re = 0, *image_Im = 0;int nRow, nCol, i, j, cy, cx;double scale, shift, tmp13, tmp24;image_Re = cvCreateImage(cvGetSize(src), IPL_DEPTH_64F, 1);//Imaginary partimage_Im = cvCreateImage(cvGetSize(src), IPL_DEPTH_64F, 1);cvSplit( src, image_Re, image_Im, 0, 0 );//具体原理见冈萨雷斯数字图像处理p123// Compute the magnitude of the spectrum Mag = sqrt(Re^2 + Im^2)//计算傅里叶谱cvPow( image_Re, image_Re, 2.0);cvPow( image_Im, image_Im, 2.0);cvAdd( image_Re, image_Im, image_Re);cvPow( image_Re, image_Re, 0.5 );//对数变换以增强灰度级细节(这种变换使以窄带低灰度输入图像值映射//一宽带输出值,具体可见冈萨雷斯数字图像处理p62)// Compute log(1 + Mag);cvAddS( image_Re, cvScalar(1.0), image_Re ); // 1 + MagcvLog( image_Re, image_Re ); // log(1 + Mag)//Rearrange the quadrants of Fourier image so that the origin is at the image centernRow = src->height;nCol = src->width;cy = nRow/2; // image centercx = nCol/2;//CV_IMAGE_ELEM为OpenCV定义的宏,用来读取图像的像素值,这一部分就是进行中心变换for( j = 0; j < cy; j++ ){for( i = 0; i < cx; i++ ){//中心化,将整体份成四块进行对角交换tmp13 = CV_IMAGE_ELEM( image_Re, double, j, i);CV_IMAGE_ELEM( image_Re, double, j, i) = CV_IMAGE_ELEM(image_Re, double, j+cy, i+cx);CV_IMAGE_ELEM( image_Re, double, j+cy, i+cx) = tmp13;tmp24 = CV_IMAGE_ELEM( image_Re, double, j, i+cx);CV_IMAGE_ELEM( image_Re, double, j, i+cx) =CV_IMAGE_ELEM( image_Re, double, j+cy, i);CV_IMAGE_ELEM( image_Re, double, j+cy, i) = tmp24;}}//归一化处理将矩阵的元素值归一为[0,255]//[(f(x,y)-minVal)/(maxVal-minVal)]*255double minVal = 0, maxVal = 0;// Localize minimum and maximum valuescvMinMaxLoc( image_Re, &minVal, &maxVal );// Normalize image (0 - 255) to be observed as an u8 imagescale = 255/(maxVal - minVal);shift = -minVal * scale;cvConvertScale(image_Re, dst, scale, shift);cvReleaseImage(&image_Re);cvReleaseImage(&image_Im);}void CCVMFCView::OnFuliyeTransform(){IplImage *src;IplImage *Fourier; //傅里叶系数IplImage *dst ;IplImage *ImageRe;IplImage *ImageIm;IplImage *Image;IplImage *ImageDst;double m,M;double scale;double shift;//src = workImg;if(workImg->nChannels==3)OnColorToGray();src=cvCreateImage(cvGetSize(workImg),IPL_DEPTH_64F,workImg->nChannels); //源图像imageClone(workImg,&src);cvFlip(src);Fourier = cvCreateImage(cvGetSize(src),IPL_DEPTH_64F,2);dst = cvCreateImage(cvGetSize(src),IPL_DEPTH_64F,2);ImageRe = cvCreateImage(cvGetSize(src),IPL_DEPTH_64F,1);ImageIm = cvCreateImage(cvGetSize(src),IPL_DEPTH_64F,1);Image = cvCreateImage(cvGetSize(src),src->depth,src->nChannels);ImageDst = cvCreateImage(cvGetSize(src),src->depth,src->nChannels);fft2(src,Fourier); //傅里叶变换fft2shift(Fourier, Image); //中心化cvDFT(Fourier,dst,CV_DXT_INV_SCALE);//实现傅里叶逆变换,并对结果进行缩放cvSplit(dst,ImageRe,ImageIm,0,0);cvNamedWindow("源图像",0);cvShowImage("源图像",src); //对数组每个元素平方并存储在第二个参数中cvPow(ImageRe,ImageRe,2); cvPow(ImageIm,ImageIm,2);cvAdd(ImageRe,ImageIm,ImageRe,NULL);cvPow(ImageRe,ImageRe,0.5);cvMinMaxLoc(ImageRe,&m,&M,NULL,NULL);scale = 255/(M - m);shift = -m * scale;//将shift加在ImageRe各元素按比例缩放的结果上,存储为ImageDstcvConvertScale(ImageRe,ImageDst,scale,shift);cvNamedWindow("傅里叶谱",0);cvShowImage("傅里叶谱",Image);cvNamedWindow("傅里叶逆变换",0);cvShowImage("傅里叶逆变换",ImageDst);//释放图像cvWaitKey(10000);cvReleaseImage(&src);cvReleaseImage(&Image);cvReleaseImage(&ImageIm);cvReleaseImage(&ImageRe);cvReleaseImage(&Fourier);cvReleaseImage(&dst);cvReleaseImage(&ImageDst);Invalidate();}
from: http://blog.csdn.net/abcjennifer/article/details/7359952
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