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380 lines
16 KiB
C++
380 lines
16 KiB
C++
/*
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#
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# File : radon_transform2d.cpp
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# ( C++ source file )
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#
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# Description : An implementation of the Radon Transform.
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# This file is a part of the CImg Library project.
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# ( http://cimg.eu )
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#
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# Copyright : David G. Starkweather
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# ( starkdg@sourceforge.net - starkweatherd@cox.net )
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#
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# License : CeCILL v2.0
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# ( http://www.cecill.info/licences/Licence_CeCILL_V2-en.html )
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#
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# This software is governed by the CeCILL license under French law and
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# abiding by the rules of distribution of free software. You can use,
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# modify and/ or redistribute the software under the terms of the CeCILL
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# license as circulated by CEA, CNRS and INRIA at the following URL
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# "http://www.cecill.info".
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#
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# As a counterpart to the access to the source code and rights to copy,
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# modify and redistribute granted by the license, users are provided only
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# with a limited warranty and the software's author, the holder of the
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# economic rights, and the successive licensors have only limited
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# liability.
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#
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# In this respect, the user's attention is drawn to the risks associated
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# with loading, using, modifying and/or developing or reproducing the
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# software by the user in light of its specific status of free software,
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# that may mean that it is complicated to manipulate, and that also
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# therefore means that it is reserved for developers and experienced
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# professionals having in-depth computer knowledge. Users are therefore
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# encouraged to load and test the software's suitability as regards their
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# requirements in conditions enabling the security of their systems and/or
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# data to be ensured and, more generally, to use and operate it in the
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# same conditions as regards security.
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#
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# The fact that you are presently reading this means that you have had
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# knowledge of the CeCILL license and that you accept its terms.
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#
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*/
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#include "CImg.h"
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using namespace cimg_library;
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#ifndef cimg_imagepath
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#define cimg_imagepath "img/"
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#endif
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#define ROUNDING_FACTOR(x) (((x) >= 0) ? 0.5 : -0.5)
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CImg<double> GaussianKernel(double rho);
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CImg<float> ApplyGaussian(CImg<unsigned char> im,double rho);
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CImg<unsigned char> RGBtoGrayScale(CImg<unsigned char> &im);
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int GetAngle(int dy,int dx);
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CImg<unsigned char> CannyEdges(CImg<float> im, double T1, double T2,bool doHysteresis);
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CImg<> RadonTransform(CImg<unsigned char> im,int N);
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// Main procedure
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//----------------
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int main(int argc,char **argv) {
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cimg_usage("Illustration of the Radon Transform");
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const char *file = cimg_option("-f",cimg_imagepath "parrot.ppm","path and file name");
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const double sigma = cimg_option("-r",1.0,"blur coefficient for gaussian low pass filter (lpf)"),
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thresh1 = cimg_option("-t1",0.50,"lower threshold for canny edge detector"),
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thresh2 = cimg_option("-t2",1.25,"upper threshold for canny edge detector");;
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const int N = cimg_option("-n",64,"number of angles to consider in the Radon transform - should be a power of 2");
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//color to draw lines
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const unsigned char green[] = {0,255,0};
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CImg<unsigned char> src(file);
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int rhomax = (int)std::sqrt((double)(src.width()*src.width() + src.height()*src.height()))/2;
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if (cimg::dialog(cimg::basename(argv[0]),
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"Instructions:\n"
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"Click on space bar or Enter key to display Radon transform of given image\n"
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"Click on anywhere in the transform window to display a \n"
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"corresponding green line in the original image\n",
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"Start", "Quit",0,0,0,0,
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src.get_resize(100,100,1,3),true)) std::exit(0);
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//retrieve a grayscale from the image
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CImg<unsigned char> grayScaleIm;
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if ((src.spectrum() == 3) && (src.width() > 0) && (src.height() > 0) && (src.depth() == 1))
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grayScaleIm = (CImg<unsigned char>)src.get_norm(0).quantize(255,false);
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else if ((src.spectrum() == 1)&&(src.width() > 0) && (src.height() > 0) && (src.depth() == 1))
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grayScaleIm = src;
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else { // image in wrong format
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if (cimg::dialog(cimg::basename("wrong file format"),
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"Incorrect file format\n","OK",0,0,0,0,0,
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src.get_resize(100,100,1,3),true)) std::exit(0);
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}
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//blur the image with a Gaussian lpf to remove spurious edges (e.g. noise)
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CImg<float> blurredIm = ApplyGaussian(grayScaleIm,sigma);
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//use canny edge detection algorithm to get edge map of the image
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//- the threshold values are used to perform hysteresis in the edge detection process
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CImg<unsigned char> cannyEdgeMap = CannyEdges(blurredIm,thresh1,thresh2,false);
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CImg<unsigned char> radonImage(500,400,1,1,0);
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//display the two windows
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CImgDisplay dispImage(src,"original image");
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dispImage.move(CImgDisplay::screen_width()/8,CImgDisplay::screen_height()/8);
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CImgDisplay dispRadon(radonImage,"Radon Transform");
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dispRadon.move(CImgDisplay::screen_width()/4,CImgDisplay::screen_height()/4);
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CImgDisplay dispCanny(cannyEdgeMap,"canny edges");
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//start main display loop
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while (!dispImage.is_closed() && !dispRadon.is_closed() &&
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!dispImage.is_keyQ() && !dispRadon.is_keyQ() &&
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!dispImage.is_keyESC() && !dispRadon.is_keyESC()) {
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CImgDisplay::wait(dispImage,dispRadon);
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if (dispImage.is_keySPACE() || dispRadon.is_keySPACE()) {
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radonImage = (CImg<unsigned char>)RadonTransform(cannyEdgeMap,N).quantize(255,false).resize(500,400);
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radonImage.display(dispRadon);
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}
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//when clicking on dispRadon window, draw line in original image window
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if (dispRadon.button())
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{
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const double rho = dispRadon.mouse_y()*rhomax/dispRadon.height(),
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theta = (dispRadon.mouse_x()*N/dispRadon.width())*2*cimg::PI/N,
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x = src.width()/2 + rho*std::cos(theta),
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y = src.height()/2 + rho*std::sin(theta);
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const int x0 = (int)(x + 1000*std::cos(theta + cimg::PI/2)),
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y0 = (int)(y + 1000*std::sin(theta + cimg::PI/2)),
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x1 = (int)(x - 1000*std::cos(theta + cimg::PI/2)),
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y1 = (int)(y - 1000*std::sin(theta + cimg::PI/2));
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src.draw_line(x0,y0,x1,y1,green,1.0f,0xF0F0F0F0).display(dispImage);
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}
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}
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return 0;
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}
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/**
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* PURPOSE: create a 5x5 gaussian kernel matrix
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* PARAM rho - gaussiam equation parameter (default = 1.0)
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* RETURN CImg<double> the gaussian kernel
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**/
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CImg<double> GaussianKernel(double sigma = 1.0)
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{
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CImg<double> resultIm(5,5,1,1,0);
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int midX = 3, midY = 3;
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cimg_forXY(resultIm,X,Y) {
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resultIm(X,Y) = std::ceil(256.0*(std::exp(-(midX*midX + midY*midY)/(2*sigma*sigma)))/(2*cimg::PI*sigma*sigma));
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}
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return resultIm;
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}
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/*
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* PURPOSE: convolve a given image with the gaussian kernel
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* PARAM CImg<unsigned char> im - image to be convolved upon
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* PARAM double sigma - gaussian equation parameter
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* RETURN CImg<float> image resulting from the convolution
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* */
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CImg<float> ApplyGaussian(CImg<unsigned char> im,double sigma)
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{
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CImg<float> smoothIm(im.width(),im.height(),1,1,0);
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//make gaussian kernel
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CImg<float> gk = GaussianKernel(sigma);
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//apply gaussian
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CImg_5x5(I,int);
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cimg_for5x5(im,X,Y,0,0,I,int) {
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float sum = 0;
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sum += gk(0,0)*Ibb + gk(0,1)*Ibp + gk(0,2)*Ibc + gk(0,3)*Ibn + gk(0,4)*Iba;
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sum += gk(1,0)*Ipb + gk(1,1)*Ipp + gk(1,2)*Ipc + gk(1,3)*Ipn + gk(1,4)*Ipa;
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sum += gk(2,0)*Icb + gk(2,1)*Icp + gk(2,2)*Icc + gk(2,3)*Icn + gk(2,4)*Ica;
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sum += gk(3,0)*Inb + gk(3,1)*Inp + gk(3,2)*Inc + gk(3,3)*Inn + gk(3,4)*Ina;
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sum += gk(4,0)*Iab + gk(4,1)*Iap + gk(4,2)*Iac + gk(4,3)*Ian + gk(4,4)*Iaa;
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smoothIm(X,Y) = sum/256;
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}
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return smoothIm;
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}
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/**
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* PURPOSE: convert a given rgb image to a MxNX1 single vector grayscale image
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* PARAM: CImg<unsigned char> im - rgb image to convert
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* RETURN: CImg<unsigned char> grayscale image with MxNx1x1 dimensions
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**/
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CImg<unsigned char> RGBtoGrayScale(CImg<unsigned char> &im)
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{
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CImg<unsigned char> grayImage(im.width(),im.height(),im.depth(),1,0);
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if (im.spectrum() == 3) {
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cimg_forXYZ(im,X,Y,Z) {
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grayImage(X,Y,Z,0) = (unsigned char)(0.299*im(X,Y,Z,0) + 0.587*im(X,Y,Z,1) + 0.114*im(X,Y,Z,2));
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}
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}
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grayImage.quantize(255,false);
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return grayImage;
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}
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/**
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* PURPOSE: aux. function used by CannyEdges to quantize an angle theta given by gradients, dx and dy
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* into 0 - 7
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* PARAM: dx,dy - gradient magnitudes
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* RETURN int value between 0 and 7
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**/
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int GetAngle(int dy,int dx)
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{
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double angle = cimg::abs(std::atan2((double)dy,(double)dx));
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if ((angle >= -cimg::PI/8)&&(angle <= cimg::PI/8))//-pi/8 to pi/8 => 0
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return 0;
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else if ((angle >= cimg::PI/8)&&(angle <= 3*cimg::PI/8))//pi/8 to 3pi/8 => pi/4
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return 1;
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else if ((angle > 3*cimg::PI/8)&&(angle <= 5*cimg::PI/8))//3pi/8 to 5pi/8 => pi/2
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return 2;
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else if ((angle > 5*cimg::PI/8)&&(angle <= 7*cimg::PI/8))//5pi/8 to 7pi/8 => 3pi/4
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return 3;
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else if (((angle > 7*cimg::PI/8) && (angle <= cimg::PI)) ||
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((angle <= -7*cimg::PI/8)&&(angle >= -cimg::PI))) //-7pi/8 to -pi OR 7pi/8 to pi => pi
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return 4;
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else return 0;
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}
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/**
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* PURPOSE: create an edge map of the given image with hysteresis using thresholds T1 and T2
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* PARAMS: CImg<float> im the image to perform edge detection on
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* T1 lower threshold
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* T2 upper threshold
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* RETURN CImg<unsigned char> edge map
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**/
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CImg<unsigned char> CannyEdges(CImg<float> im, double T1, double T2, bool doHysteresis=false)
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{
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CImg<unsigned char> edges(im);
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CImg<float> secDerivs(im);
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secDerivs.fill(0);
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edges.fill(0);
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CImgList<float> gradients = im.get_gradient("xy",1);
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int image_width = im.width();
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int image_height = im.height();
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cimg_forXY(im,X,Y) {
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double Gr = std::sqrt(std::pow((double)gradients[0](X,Y),2.0) + std::pow((double)gradients[1](X,Y),2.0));
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double theta = GetAngle(Y,X);
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//if Gradient magnitude is positive and X,Y within the image
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//take the 2nd deriv in the appropriate direction
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if ((Gr > 0)&&(X < image_width - 2)&&(Y < image_height - 2)) {
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if (theta == 0)
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secDerivs(X,Y) = im(X + 2,Y) - 2*im(X + 1,Y) + im(X,Y);
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else if (theta == 1)
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secDerivs(X,Y) = im(X + 2,Y + 2) - 2*im(X + 1,Y + 1) + im(X,Y);
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else if (theta == 2)
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secDerivs(X,Y) = im(X,Y + 2) - 2*im(X,Y + 1) + im(X,Y);
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else if (theta == 3)
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secDerivs(X,Y) = im(X + 2,Y + 2) - 2*im(X + 1,Y + 1) + im(X,Y);
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else if (theta == 4)
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secDerivs(X,Y) = im(X + 2,Y) - 2*im(X + 1,Y) + im(X,Y);
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}
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}
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//for each 2nd deriv that crosses a zero point and magnitude passes the upper threshold.
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//Perform hysteresis in the direction of the gradient, rechecking the gradient
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//angle for each pixel that meets the threshold requirement. Stop checking when
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//the lower threshold is not reached.
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CImg_5x5(I,float);
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cimg_for5x5(secDerivs,X,Y,0,0,I,float) {
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if ( (Ipp*Ibb < 0) ||
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(Ipc*Ibc < 0)||
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(Icp*Icb < 0) ) {
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double Gr = std::sqrt(std::pow((double)gradients[0](X,Y),2.0) + std::pow((double)gradients[1](X,Y),2.0));
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int dir = GetAngle(Y,X);
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int Xt = X, Yt = Y, delta_x = 0, delta_y=0;
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double GRt = Gr;
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if (Gr >= T2)
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edges(X,Y) = 255;
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//work along the gradient in one direction
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if (doHysteresis) {
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while ((Xt > 0) && (Xt < image_width - 1) && (Yt > 0) && (Yt < image_height - 1)) {
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switch (dir){
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case 0 : delta_x=0;delta_y=1;break;
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case 1 : delta_x=1;delta_y=1;break;
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case 2 : delta_x=1;delta_y=0;break;
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case 3 : delta_x=1;delta_y=-1;break;
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case 4 : delta_x=0;delta_y=1;break;
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}
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Xt += delta_x;
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Yt += delta_y;
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GRt = std::sqrt(std::pow((double)gradients[0](Xt,Yt),2.0) + std::pow((double)gradients[1](Xt,Yt),2.0));
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dir = GetAngle(Yt,Xt);
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if (GRt >= T1)
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edges(Xt,Yt) = 255;
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}
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//work along gradient in other direction
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Xt = X; Yt = Y;
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while ((Xt > 0) && (Xt < image_width - 1) && (Yt > 0) && (Yt < image_height - 1)) {
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switch (dir){
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case 0 : delta_x=0;delta_y=1;break;
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case 1 : delta_x=1;delta_y=1;break;
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case 2 : delta_x=1;delta_y=0;break;
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case 3 : delta_x=1;delta_y=-1;break;
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case 4 : delta_x=0;delta_y=1;break;
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}
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Xt -= delta_x;
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Yt -= delta_y;
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GRt = std::sqrt(std::pow((double)gradients[0](Xt,Yt),2.0) + std::pow((double)gradients[1](Xt,Yt),2.0));
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dir = GetAngle(Yt,Xt);
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if (GRt >= T1)
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edges(Xt,Yt) = 255;
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}
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}
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}
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}
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return edges;
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}
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/**
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* PURPOSE: perform radon transform of given image
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* PARAM: CImg<unsigned char> im - image to detect lines
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* int N - number of angles to consider (should be a power of 2)
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* (the values of N will be spread over 0 to 2PI)
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* RETURN CImg<unsigned char> - transform of given image of size, N x D
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* D = rhomax = sqrt(dimx*dimx + dimy*dimy)/2
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**/
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CImg<> RadonTransform(CImg<unsigned char> im,int N) {
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int image_width = im.width();
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int image_height = im.height();
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//calc offsets to center the image
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float xofftemp = image_width/2.0f - 1;
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float yofftemp = image_height/2.0f - 1;
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int xoffset = (int)std::floor(xofftemp + ROUNDING_FACTOR(xofftemp));
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int yoffset = (int)std::floor(yofftemp + ROUNDING_FACTOR(yofftemp));
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float dtemp = (float)std::sqrt((double)(xoffset*xoffset + yoffset*yoffset));
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int D = (int)std::floor(dtemp + ROUNDING_FACTOR(dtemp));
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CImg<> imRadon(N,D,1,1,0);
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//for each angle k to consider
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for (int k= 0 ; k < N; k++) {
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//only consider from PI/8 to 3PI/8 and 5PI/8 to 7PI/8
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//to avoid computational complexity of a steep angle
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if (k == 0){k = N/8;continue;}
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else if (k == (3*N/8 + 1)){ k = 5*N/8;continue;}
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else if (k == 7*N/8 + 1){k = N; continue;}
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//for each rho length, determine linear equation and sum the line
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//sum is to sum the values along the line at angle k2pi/N
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//sum2 is to sum the values along the line at angle k2pi/N + N/4
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//The sum2 is performed merely by swapping the x,y axis as if the image were rotated 90 degrees.
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for (int d=0; d < D; d++) {
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double theta = 2*k*cimg::PI/N;//calculate actual theta
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double alpha = std::tan(theta + cimg::PI/2);//calculate the slope
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double beta_temp = -alpha*d*std::cos(theta) + d*std::sin(theta);//y-axis intercept for the line
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int beta = (int)std::floor(beta_temp + ROUNDING_FACTOR(beta_temp));
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//for each value of m along x-axis, calculate y
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//if the x,y location is within the boundary for the respective image orientations, add to the sum
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unsigned int sum1 = 0,
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sum2 = 0;
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int M = (image_width >= image_height) ? image_width : image_height;
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for (int m=0;m < M; m++) {
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//interpolate in-between values using nearest-neighbor approximation
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//using m,n as x,y indices into image
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double n_temp = alpha*(m - xoffset) + beta;
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int n = (int)std::floor(n_temp + ROUNDING_FACTOR(n_temp));
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if ((m < image_width) && (n + yoffset >= 0) && (n + yoffset < image_height))
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{
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sum1 += im(m, n + yoffset);
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}
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n_temp = alpha*(m - yoffset) + beta;
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n = (int)std::floor(n_temp + ROUNDING_FACTOR(n_temp));
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if ((m < image_height)&&(n + xoffset >= 0)&&(n + xoffset < image_width))
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{
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sum2 += im(-(n + xoffset) + image_width - 1, m);
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}
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}
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//assign the sums into the result matrix
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imRadon(k,d) = (float)sum1;
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//assign sum2 to angle position for theta + PI/4
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imRadon(((k + N/4)%N),d) = (float)sum2;
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}
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}
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return imRadon;
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}
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/* references:
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* 1. See Peter Toft's thesis on the Radon transform: http://petertoft.dk/PhD/index.html
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* While I changed his basic algorithm, the main idea is still the same and provides an excellent explanation.
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*
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* */
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