# How to calculate perspective transform for OpenCV from rotation angles?

I want to calculate perspective transform (a matrix for warpPerspective function) starting from angles of rotation and distance to the object.

How to do that?

I found the code somewhere on OE. Sample program is below:

``````#include <opencv2/objdetect/objdetect.hpp>
#include <opencv2/highgui/highgui.hpp>
#include <opencv2/imgproc/imgproc.hpp>

#include <iostream>
#include <math.h>

using namespace std;
using namespace cv;

Mat frame;

int alpha_int;
int dist_int;
int f_int;

double w;
double h;
double alpha;
double dist;
double f;

void redraw() {

alpha = (double)alpha_int/1000.;
//dist = 1./(dist_int+1);
//dist = dist_int+1;
dist = dist_int-50;
f = f_int+1;

cout << "alpha = " << alpha << endl;
cout << "dist = " << dist << endl;
cout << "f = " << f << endl;

// Projection 2D -> 3D matrix
Mat A1 = (Mat_<double>(4,3) <<
1,              0,              -w/2,
0,              1,              -h/2,
0,              0,              1,
0,              0,              1);

// Rotation matrices around the X axis
Mat R = (Mat_<double>(4, 4) <<
1,              0,              0,              0,
0,              cos(alpha),     -sin(alpha),    0,
0,              sin(alpha),     cos(alpha),     0,
0,              0,              0,              1);

// Translation matrix on the Z axis
Mat T = (Mat_<double>(4, 4) <<
1,              0,              0,              0,
0,              1,              0,              0,
0,              0,              1,              dist,
0,              0,              0,              1);

// Camera Intrisecs matrix 3D -> 2D
Mat A2 = (Mat_<double>(3,4) <<
f,              0,              w/2,            0,
0,              f,              h/2,            0,
0,              0,              1,              0);

Mat m = A2 * (T * (R * A1));

cout << "R=" << endl << R << endl;
cout << "A1=" << endl << A1 << endl;
cout << "R*A1=" << endl << (R*A1) << endl;
cout << "T=" << endl << T << endl;
cout << "T * (R * A1)=" << endl << (T * (R * A1)) << endl;
cout << "A2=" << endl << A2 << endl;
cout << "A2 * (T * (R * A1))=" << endl << (A2 * (T * (R * A1))) << endl;
cout << "m=" << endl << m << endl;

Mat frame1;

warpPerspective( frame, frame1, m, frame.size(), INTER_CUBIC | WARP_INVERSE_MAP);

imshow("Frame", frame);
imshow("Frame1", frame1);
}

void callback(int, void* ) {
redraw();
}

void main() {

imshow("Frame", frame);

w = frame.size().width;
h = frame.size().height;

createTrackbar("alpha", "Frame", &alpha_int, 100, &callback);
dist_int = 50;
createTrackbar("dist", "Frame", &dist_int, 100, &callback);
createTrackbar("f", "Frame", &f_int, 100, &callback);

redraw();

waitKey(-1);
}
``````

But unfortunately, this transform does something strange

Why? What is another half of image above when `alpha>0`? And how to rotate around other axes? Why `dist` works so strange?

-
it looks like your width and height values are single pixels. –  Geoff Jun 13 '13 at 13:37
setting hundreds change nothing –  Suzan Cioc Jun 13 '13 at 14:06
To know why this code works the way it works take a look at the equations in the following paper eee.nuigalway.ie/Research/car/documents/docualain_issc10.pdf . I though still feel this code is bit weird. I would change `alpha = (double)alpha_int/1000.;` to `alpha = (double)alpha_int*CV_PI/180.;` and also I not sure how A1 matrix is calculated. I would set A1 as `Mat A1 = (Mat_<double>(4,3) << 1, 0, -w/2, 0, 0, 0, //Y-axis zero 0, 1, -h/2, 0, 0, 1);` –  enthusiasticgeek Jul 21 '13 at 22:26
And of course you have rotation around x-axis [i.e. pitch or tilt] (take a look at the diagram in the pdf listed above). If your camera is rotated with roll 'gamma' you will have to multiply by another 4x4 matrix with gamma parameter. –  enthusiasticgeek Jul 21 '13 at 22:32
I would remove dist_int track bar and set dist = -height/sin(alpha) (make sure alpha>0). height is the height where camera is placed from the ground. –  enthusiasticgeek Jul 21 '13 at 22:48

I have had the luxury of time to think out both math and code. I did this a year or two ago. I even typeset this in beautiful LaTeX.

I intentionally designed my solution so that no matter what rotation angles are provided, the entire input image is contained, centered, within the output frame, which is otherwise black.

The arguments to my `warpImage` function are rotation angles in all 3 axes, the scale factor and the vertical field-of-view angle. The function outputs the warp matrix, the output image and the corners of the source image within the output image.

## The Math (for code, look below)

The LaTeX source code is here.

## The Code (for math, look above)

Here is a test application that warps the camera

``````#include <opencv2/core/core.hpp>
#include <opencv2/imgproc/imgproc.hpp>
#include <opencv2/highgui/highgui.hpp>
#include <math.h>

using namespace cv;
using namespace std;

void warpMatrix(Size   sz,
double theta,
double phi,
double gamma,
double scale,
double fovy,
Mat&   M,
vector<Point2f>* corners){

double halfFovy=fovy*0.5;
double d=hypot(sz.width,sz.height);
double n=h-(d/2.0);
double f=h+(d/2.0);

Mat F=Mat(4,4,CV_64FC1);//Allocate 4x4 transformation matrix F
Mat Rtheta=Mat::eye(4,4,CV_64FC1);//Allocate 4x4 rotation matrix around Z-axis by theta degrees
Mat Rphi=Mat::eye(4,4,CV_64FC1);//Allocate 4x4 rotation matrix around X-axis by phi degrees
Mat Rgamma=Mat::eye(4,4,CV_64FC1);//Allocate 4x4 rotation matrix around Y-axis by gamma degrees

Mat T=Mat::eye(4,4,CV_64FC1);//Allocate 4x4 translation matrix along Z-axis by -h units
Mat P=Mat::zeros(4,4,CV_64FC1);//Allocate 4x4 projection matrix

//Rtheta
Rtheta.at<double>(0,0)=Rtheta.at<double>(1,1)=ct;
Rtheta.at<double>(0,1)=-st;Rtheta.at<double>(1,0)=st;
//Rphi
Rphi.at<double>(1,1)=Rphi.at<double>(2,2)=cp;
Rphi.at<double>(1,2)=-sp;Rphi.at<double>(2,1)=sp;
//Rgamma
Rgamma.at<double>(0,0)=Rgamma.at<double>(2,2)=cg;
Rgamma.at<double>(0,2)=sg;Rgamma.at<double>(2,0)=sg;

//T
T.at<double>(2,3)=-h;
//P
P.at<double>(2,2)=-(f+n)/(f-n);
P.at<double>(2,3)=-(2.0*f*n)/(f-n);
P.at<double>(3,2)=-1.0;
//Compose transformations
F=P*T*Rphi*Rtheta*Rgamma;//Matrix-multiply to produce master matrix

//Transform 4x4 points
double ptsIn [4*3];
double ptsOut[4*3];
double halfW=sz.width/2, halfH=sz.height/2;

ptsIn[0]=-halfW;ptsIn[ 1]= halfH;
ptsIn[3]= halfW;ptsIn[ 4]= halfH;
ptsIn[6]= halfW;ptsIn[ 7]=-halfH;
ptsIn[9]=-halfW;ptsIn[10]=-halfH;
ptsIn[2]=ptsIn[5]=ptsIn[8]=ptsIn[11]=0;//Set Z component to zero for all 4 components

Mat ptsInMat(1,4,CV_64FC3,ptsIn);
Mat ptsOutMat(1,4,CV_64FC3,ptsOut);

perspectiveTransform(ptsInMat,ptsOutMat,F);//Transform points

//Get 3x3 transform and warp image
Point2f ptsInPt2f[4];
Point2f ptsOutPt2f[4];

for(int i=0;i<4;i++){
Point2f ptIn (ptsIn [i*3+0], ptsIn [i*3+1]);
Point2f ptOut(ptsOut[i*3+0], ptsOut[i*3+1]);
ptsInPt2f[i]  = ptIn+Point2f(halfW,halfH);
ptsOutPt2f[i] = (ptOut+Point2f(1,1))*(sideLength*0.5);
}

M=getPerspectiveTransform(ptsInPt2f,ptsOutPt2f);

if(corners){
corners->clear();
corners->push_back(ptsOutPt2f[0]);//Push Top Left corner
corners->push_back(ptsOutPt2f[1]);//Push Top Right corner
corners->push_back(ptsOutPt2f[2]);//Push Bottom Right corner
corners->push_back(ptsOutPt2f[3]);//Push Bottom Left corner
}
}

void warpImage(const Mat &src,
double    theta,
double    phi,
double    gamma,
double    scale,
double    fovy,
Mat&      dst,
Mat&      M,
vector<Point2f> &corners){
double halfFovy=fovy*0.5;
double d=hypot(src.cols,src.rows);

warpMatrix(src.size(),theta,phi,gamma, scale,fovy,M,&corners);//Compute warp matrix
warpPerspective(src,dst,M,Size(sideLength,sideLength));//Do actual image warp
}

int main(void){
Mat m, disp, warp;
vector<Point2f> corners;
VideoCapture cap(0);

while(cap.isOpened()){
cap >> m;
warpImage(m, 5, 50, 0, 1, 30, disp, warp, corners);
imshow("Disp", disp);
}
}
``````
-
As a small note, although my derivations only include two rotation matrices (Rtheta and Rphi, the Z and X-axis rotation matrices) and therefore only two rotation axes, the code does contain 3 rotation matrices (Rtheta, Rphi and Rgamma), covering Z, X and Y rotations. –  Iwillnotexist Idonotexist Nov 23 '13 at 5:42
Your math produces a bigger resolution than the original image which is expected for the worse case scenario yaw. Although if I discarded the yaw transformation I would expect the resolution to not be changed, however with zero yaw and normal resolution i get a clipped image. Can you explain me why? –  aiwarrior Jul 23 at 17:31
Are you sure it's clipped? The way I calculated the distance, with no rotation the output image has precisely the same resolution as the input image (as though it had been copied), except that it is centered within a large black padding. The output therefore has more pixels, without having more (or less) resolution. Shrinking it to make it fit within the same size as the input image will of course make it look shrunk. If you want to crop, you can use the corner points that I compute to calculate the tightest bounding box. –  Iwillnotexist Idonotexist Jul 23 at 17:48
@aiwarrior The code right now is designed s.t. the image is being rotated at a fixed position in front of you, and that the center of the image is always at the same offset (x,y) in the center of the output image for a given scale, which implies that for a given scale, the output image is always the same size, and for scale = 1.0, angles 0 the input image is reproduced pixel-for-pixel within the larger output image. I take it you instead want the smallest image fully containing the warped input? –  Iwillnotexist Idonotexist Jul 24 at 0:47
Thank you a lot. One small question though. Why translate z by the hypotenuse and not by d/(2 * tg(fov/2)) –  aiwarrior Aug 2 at 21:41