I am trying to calculate the 3x3 calibration matrix P of a camera based on 2D to 3D point correspondences as described in this paper http://cronos.rutgers.edu/~meer/TEACHTOO/PAPERS/zhang.pdf (section 2.3) using python 2.7. I have been able to find an initial estimate of P, but now need to refine it using the Levenberg-Marquardt Algorithm (2.3.4). It appears to me that this can be done with scipy.optimize.minpack.leastsq. However, my attemps at implementing this function have failed. Here is a simplified version of what I have (M is a numpy array of homogenized 3d points in the format (x,y,z,1) with a shape of (18,4) and m is a numpy array of homogenized 2d points in the format (u,v,1) with a shape of (18,3)):
import numpy as N from scipy.optimize.minpack import leastsq def e(P,M,m): a = P.dot(M.T) print a.shape b = m.T-a b1 = b b2 = b b3 = b dist = sqrt((b1**2)+(b2**2)+(b3**2)) return dist P = N.array( [ [4.66135353e+01,1.24341518e+02,-9.07923056e+00,9.59292826e+02], [-3.60062368e+01,3.56319152e+01,1.14245572e+02,2.32061401e-02], [-4.04188199e-02,4.00793699e-02,-9.48804649e-03,1.00000e+00] ] ) m =  M =  #define m list and M list for i in range(0,len(uv)): uv[i].append(1) #uv is unhomogenized uv coordinate list (source left out to simplify) xyz[i].append(1) #xyz is unhomogenized xyz coordinate list (source left out to simplify) m.append(N.array( [ [uv[i]],[uv[i]],[uv[i]] ] )) m = N.array( uv ) M = N.array( xyz ) #the shape of m is (18,3) and the shape of M is (18,4) P_new, success = leastsq(e, P, args=(M,m))
I think the problem is with the M and m variables, the arrays of vectors. I looked at an example for the scipy.optimize.lstsq function and I could get that to work but it had args with only one dimension.
Does anyone know what I am doing wrong here? I am fairly new to programming so take it easy on me if this is idiotic haha. Thanks so much to all who read this and let me know if I can provide anymore info