# How to create a 2D perspective transform matrix from individual components?

I am trying to create a 2D perspective transform matrix from individual components like translation, rotation, scale, shear. But at the end the matrix is not producing a true perspective effect like the image below. I think I am missing some component in the code that I wrote to create the matrix. Could some one help me add the missing components and their formulation in the below function? I have used opencv library for my code ``````cv::Mat getPerspMatrix2D( double rz, double s, double tx, double ty ,double shx, double shy)
{

cv::Mat R = (cv::Mat_<double>(3,3) <<
cos(rz), -sin(rz), 0,
sin(rz), cos(rz), 0,
0, 0, 1);

cv::Mat S = (cv::Mat_<double>(3,3) <<
s, 0, 0,
0, s, 0,
0, 0, 1);

cv::Mat Sh = (cv::Mat_<double>(3,3) <<
1, shx, 0,
shy, 1, 0,
0, 0, 1);

cv::Mat T = (cv::Mat_<double>(3,3) <<
1, 0, tx,
0, 1, ty,
0, 0, 1);

return T * Sh * S * R;
}
``````
• Take a look at : docs.opencv.org/3.4.0/da/d6e/… Aug 6, 2018 at 20:24
• This link shows how to derive perspective transform from point pairs. I would like to manipulate different components of a perspective transform. Currently I have rotation, translation, scale, shear as the transform components. Is there any other component responsible for perspective transform? Aug 7, 2018 at 8:45

Keywords are Homography and 8DOF. Taken from 1 and 2 there exists two coefficients for perspective transformation. But it needs a 2nd step to calculate it. I'm not familiar with OpenCV but I'm hoping to answer your question a bit late in a basically way ;-)

## Step 1

You can imagine lx describes a vanishing point on the x axis. The image shows a31=lx=1. lx=100 is less transformation. For lx=0 the position is infinite far means no perspective transform = identity matrix.

``````     [1  0  0]
PL = [0  1  0]
[lx ly 1]

lx/ly are perspective foreshortening parameters
`````` ## Step 2

When you apply a right hand matrix multiplication P x [u; v; 1] you will recognize that the last value in the result is sometimes other than 1. For affine transformation it is always 1 for perspective projection not. In the 2nd step the result is scaled to make the last coefficient 1. This is a part of the effect. `````` Image' = P4 x P3 x P2 x P1 x Image
1. I would translate the center of the blue rectangle to the origin `tx=-w/2` and `ty=-h/2` = P1.
2. Apply projective projection with `ly = h` (to make both sides at an angle)