# Transformation of coordinates, Concept

i want to convert x,y,z coordinates to polar coordinates. I am getting (-) in y coordiantes. Can someone explain me why I am getting it. It would be great help.

I am reading these values (xyz , az_elev_r) from a software and can't be changed.I am just not sure of the order of angles( az & elev). Using my code I get -y instead of y. It means there is 180 rotation.My code is:

``````xyz=[-0.564 3.689 -0.735;
2.011 5.067 -1.031;
-1.181 3.943 -1.825; % Reference values
];
``````

%% az_elev_r-->xyz

`````` az_elev_r=[ 261.30 -11.24 3.80;
291.65 -10.692 5.548;
253.34 -23.897 4.50]; % Also Reference (degree)

r=az_elev_r(:,3);
az=az_elev_r(:,1);
elev=az_elev_r(:,2);

x=r.*cos(az).*cos(elev)
y=r.*sin(az).*cos(elev)
z=r.*sin(elev)
``````
-

Your `az_elev_r` matrix is not consistent with your `xyz` reference.

``````>> [az, el, r] = cart2sph(xyz(:,1), xyz(:,2), xyz(:,3));
ans =
98.6924675475501
68.3527736950233
106.673911589314
``````

Your answers are consistent with the values returned by the `sph2cart` function. (Example starts with your original input, before the `dec2rad` replacement.

``````>> [x, y, z] = sph2cart(deg2rad(az_elev_r(:,1)), deg2rad(az_elev_r(:,2)), az_elev_r(:,3))
x =
-0.563766229670505
2.01131973806906
-1.17951822049783
y =
-3.68422880893852
-5.06709019311118
-3.94153436658676
z =
-0.740692730942158
-1.02931719412937
-1.82292172199717
``````

Incidentally, you're code will be more readable if you just use the `sph2cart` function, and work in radians, unless you are trying to understand the conversions for their own sake.

-
I am reading these values (xyz , az_elev_r) from a software and can't be changed. –  Shahgee May 3 '12 at 4:56

OpenCV has the code for conversion to polar coordinates and back. This conversion is useful for finding object rotation through correlation or otherwise creating object-centred 'rotation-independent' representation of objects. It is useful to visualize each of the polar coordinates as well as their joint image. The images below should be self_explanatory. The polar plot has angle as a horizontal axis and Radius as a vertical axis, so that 4 peaks correspond to the 4 corners of the input image. The code (C++ with OpenCV) is attached.

``````//================================
// Name        : PolarCoord.cpp
// Author      : V.Ivanchenko cudassimo@gmail.com
// Version     :
// Description : Hello World in C++, Ansi-style
//======================================

#include <iostream>
#include "opencv.hpp"
using namespace std;
using namespace cv;

#define VALID(x, y, w, h) ((x)>=0 && (y)>=0 && (x)<(w) && (y)<(h)) // validates index

/*
*   1. Original binary image HxW CV_8U
*              |
*              |
*              V
*   2. Two coordinate Mats HxW CV_32F
*              |
*              |
*              V
*   3. Visualization CV_8U
*      a. gray HxW for a single coordinate image
*      b. binary Rx360 for two coordinate images
*/

// convert a binary 2D image into two Mats with float coordiantes
void imageToCoord(const Mat& img, Mat& X, Mat& Y, bool centered = true) {
if (img.empty())
return;

int h = img.rows;
int w = img.cols;
X.create(h, w, CV_32F);
Y.create(h, w, CV_32F);
float Cx = w/2.0f;
float Cy = h/2.0f;

for (int i=0; i<h; ++i){
const uchar* img_row = img.ptr<uchar>(i);
float* x_row = X.ptr<float>(i);
float* y_row = Y.ptr<float>(i);

for (int j=0; j<w; ++j) {
if (img_row[j]>0) {
float x = j;
float y = i;
if (centered) {
x-=Cx;
y-=Cy;
}
x_row[j] = x;
y_row[j] = y;
}
} // j
} // i
} //imageToCoord()

// convert a single float ploar coord Mat to a gray image
void polarToImg(const Mat& PolarCoord, Mat& img) {
if (PolarCoord.empty())
return;

int h = PolarCoord.rows;
int w = PolarCoord.cols;
img.create(h, w, CV_8U);
float maxVal = std::numeric_limits<float>::min();

// find maxVal
for (int i=0; i<h; ++i){
const float* x_row = PolarCoord.ptr<float>(i);
for (int j=0; j<w; ++j) {
if (maxVal < x_row[j])
maxVal = x_row[j];
} // j
} // i

// create an image
if (maxVal>0) {
float k = 255.0/maxVal;
for (int i=0; i<h; ++i){
uchar* img_row = img.ptr<uchar>(i);
const float* x_row = PolarCoord.ptr<float>(i);
for (int j=0; j<w; ++j) {
img_row[j] = saturate_cast<uchar>(k*x_row[j]);
}// j
} // i
} // if
} // plarToImg()

// convert two polar coord Mats to a binary image
void polarToImg(const Mat& radius, const Mat& angle, Mat& img) {
return;

int h = angle.rows;
int w = angle.cols;
const int imgH = sqrt(h*h+w*w)+0.5f; // radius
const int imgW = 360;                 // angle, deg
img.create(imgH, imgW, CV_8U);

// create an image
for (int i=0; i<h; ++i){
const float* ang_row = angle.ptr<float>(i);

for (int j=0; j<w; ++j) {
int x = ang_row[j] + 0.5f;
int y = r_row[j] + 0.5f;

if (x>0) {
cout<<x<<endl;
}
if (VALID(x, y, imgW, imgH))
img.at<uchar>(y, x) = 255;
else {
cout<<"Invalid x, y: "<<x<<", "<<y<<endl;
}
}// j
} // i
} // plarToImg()

int main() {
cout << "Cartesian to polar" << endl; // prints "Syntax training in openCV"
const int W=400, H=400;
Mat Minput(H, W, CV_8U);
Minput(Rect(W/4, H/4, W/2, H/2)) = 255;
Mat X, Y, Angle, Radius, Mr, Mang, Mpolar;

// processing
imageToCoord(Minput, X, Y);             // extract coordinates
cartToPolar(X, Y, Radius, Angle, true);// convert coordiantes

// visualize
polarToImg(Angle, Mang);

// debug
//cout<<Mpolar<<endl;

namedWindow("input", 0);
namedWindow("angle", 0);
namedWindow("Polar", 0);

const int winw=200, winh=200;
resizeWindow("input", winw, winh);
resizeWindow("angle", winw, winh);
resizeWindow("Polar", 360, (int)sqrt(H*H + W*W));

moveWindow("input", 0, 0);
moveWindow("angle", winw, 0);