I've been trying to make Zhang's "Single-View Geometry of A Rectangle With Application to Whiteboard Image Rectification" work in Python.

Abstract and formula source from Microsoft

This came from another question here on the stack, but the code was written in Sage and no longer runs on the latest Sage version. And most of that thread was a debate about whether it was possible. It is, but making it work in Python has been a problem.

The Problem: The formula it uses to calculate the focal throws a math domain error because it tries to get a square root of a negative number. I'm not sure I've converted Zhang's formulas to Python correctly. Without the correct focal it isn't very accurate at determining the ratio of the length to width of the rectangle. With the correct focal it seems to work pretty well.

Edit: Here is the version that will run on the new Sage website. It doesn't throw an error for the frame, but it comes up with a focal and w/h ratio that are way off: https://cloud.sagemath.com/projects/a8af3fd5-1390-4e80-a12a-13f18f77fdc0/files/Sage Whiteboard rectification.sagews

Any help would be much appreciated. I've put many hours into this.

The following code is from Python 2.7

Source image for the coords in the program

import numpy as np
from numpy import matrix
from numpy import *
from math import sqrt
from math import pow

def FindAspect():


    # [zhang-single]: "Single-View Geometry of A Rectangle
    #  With Application to Whiteboard Image Rectification"
    #  by Zhenggyou Zhang
    #  http://research.microsoft.com/users/zhang/Papers/WhiteboardRectification.pdf

    # pixel coordinates of the 4 corners of the quadrangle (m1, m2, m3, m4)
    # see [zhang-single] figure 1

    # The shape in the image is a perfect square filmed with a focal of 960.

    w = 1920
    h = 1080
    u = 960
    v = 540

    # These coords work, and give a ratio of 1.1499 using the focal formula
    # If you input the focal as 960 then the second part correctly identifies
    # the ratio very accurately. 1.0025

    ##    m1x = 690.196
    ##    m1y = 998.728
    ##    m2x = 1112.58
    ##    m2y = 798.383
    ##    m3x = 690.201
    ##    m3y = 81.2587
    ##    m4x = 1112.6
    ##    m4y = 281.54

    #These coords throw an error due to focal formula sqrt of negative number.

    m1x = 849.029
    m1y = 792.363

    m2x = 1170.147
    m2y = 1019.212

    m3x = 849.033
    m3y = 287.516

    m4x = 1170.154
    m4y = 60.757

    # pixel coordinates of the principal point of the image
    # for a normal camera this will be the center of the image,
    # i.e. u0=IMAGEWIDTH/2; v0 =IMAGEHEIGHT/2
    # This assumption does not hold if the image has been cropped asymmetrically
    u0 = u
    v0 = v

    # pixel aspect ratio; for a normal camera pixels are square, so s=1
    s = 1

    # homogenous coordinates of the quadrangle
    m1 = array([m1x,m1y,1])
    m2 = array([m2x,m2y,1])
    m3 = array([m3x,m3y,1])
    m4 = array([m4x,m4y,1])

    # The following equations are later used in calculating the the focal length
    # and the rectangle's aspect ratio.

    # see [zhang-single] Equation 11, 12
    k2 = np.dot(np.cross(m1, m4), m3) / np.dot(np.cross(m2, m4), m3)
    k3 = np.dot(np.cross(m1, m4), m2) / np.dot(np.cross(m3, m4), m2)

    # see [zhang-single] Equation 14,16
    n2 = k2 * m2 - m1
    n3 = k3 * m3 - m1

    # the focal length of the camera.

    f = sqrt(
             -1 / (
             ) * (
               n2[0]*n3[0] - (n2[0]*n3[2]+n2[2]*n3[0])*u0 + n2[2]*n3[2] * u0**2
              )*s**2 + (
               n2[1]*n3[1] - (n2[1]*n3[2]+n2[2]*n3[1])*v0 + n2[2]*n3[2] * v0**2

    print 'Focal: ', f

    ##    f = 960

    # standard pinhole camera matrix
    # see [zhang-single] Equation 1

    K = np.matrix([[f,0,u0],[0,f,v0],[0,0,1]])

    #the width/height ratio of the original rectangle
    # see [zhang-single] Equation 20

    whRatio = sqrt(
                   (np.dot(np.asarray(n2 * (K.T**-1)).reshape(-1), np.asarray((K**-1).dot(n2)).reshape(-1))) /
                   (np.dot(np.asarray(n3 * (K.T**-1)).reshape(-1), np.asarray((K**-1).dot(n3)).reshape(-1)))

    print whRatio

  • I specify the error in the code. The formula for the focal throws an error because it tries to get the square root of a negative number.
    – terrachild
    Apr 10, 2015 at 10:58
  • Then could you narrow it down to that formula, and show the full traceback? Have you tried splitting the formula down to steps? Please read stackoverflow.com/help/mcve.
    – jonrsharpe
    Apr 10, 2015 at 11:00
  • Traceback rectify.py 105 ValueError: math domain error
    – terrachild
    Apr 10, 2015 at 11:02
  • Yes, I broke the focal formula down into separate parts, and they all appear to run, but the end result is a negative number. And it shouldn't be for the sqrt. The first coordinates in the program work fine. I've implemented this in Python, but I'm not sure I did it correctly.
    – terrachild
    Apr 10, 2015 at 11:06
  • what is the orginal question you refer as "This came from another question here on the stack" ? Apr 10, 2015 at 11:46


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