The approach I used to solve this problem was the following:

- Create an empty image with the desired output size.
- For every pixel in the output image find the theta and phi coordinates. (Linearly) Theta goes from -Pi to Pi and phi from 0 to Pi
- Set a projection radius R and find 3D coordinate from theta, phi and R.
- Find for how many cameras is the 3D point visible and the correspondent pixel position.
- Copy the pixel of the image where the pixel is closer to the principal point. Or any other valid criteria...

My code looks like:

```
cv::Mat panoramic;
panoramic=cv::Mat::zeros(PANO_HEIGHT,PANO_WIDTH,CV_8UC3);
double theta, phi;
double R=calibration.getSphereRadius();
int result;
double dRow=0;
double dCol=0;
for(int y = 0; y!= PANO_HEIGHT; y++){
for(int x = 0; x !=PANO_WIDTH ; x++) {
//Rescale to [-pi, pi]
theta=-(2*PI*x/(PANO_WIDTH-1)-PI); //Sign change needed.
phi=PI*y/(PANO_HEIGHT-1);
//From theta and phi find the 3D coordinates.
double globalZ=R*cos(phi);
double globalX=R*sin(phi)*cos(theta);
double globalY=R*sin(phi)*sin(theta);
float minDistanceCenter=5000; // Doesn't depend on the image.
float distanceCenter;
//From the 3D coordinates, find in how many camera falls the point!
for(int cam = 0; cam!= 6; cam++){
result=calibration.ladybugXYZtoRC(globalX, globalY, globalZ, cam, dRow, dCol);
if (result==0){ //The 3d point is visible from this camera
cv::Vec3b intensity = image[cam].at<cv::Vec3b>(dRow,dCol);
distanceCenter=sqrt(pow(dRow-imageHeight/2,2)+pow(dCol-imageWidth/2,2));
if (distanceCenter<minDistanceCenter) {
panoramic.ptr<unsigned char>(y,x)[0]=intensity.val[0];
panoramic.ptr<unsigned char>(y,x)[1]=intensity.val[1];
panoramic.ptr<unsigned char>(y,x)[2]=intensity.val[2];
minDistanceCenter=distanceCenter;
}
}
}
}
}
```