Imagine I have two (python) lists (with a limited) amount of 3D points. How do I find a rigid transformation to match the points as closely as possible. For each point of each list it is known to which other point that point corresponds. Is there an algorithm/library for this?

I found the Iterative closest point algorithm, but this assumes there is no correspondence known and it seems to be made for large point clouds. I'm talking about limited sets of 3 to 8 points.

Possible point sets (correspondence according to index in the list)

a = [[0,0,0], [1,0,0],[0,1,0]]
b = [[0,0,0.5], [1,0,1],[0,0,2]]

2 Answers 2


Turns out there is actually an analytical solution. It is described in the paper of Arun et al., 1987, Least square fitting of two 3D point sets

I wrote a testscript to test their algorithm and it seems to work fine (if you want to have a solution that minimizes the sum of the square errors, if you have an outlier this might not be ideal):

import numpy as np

##Based on Arun et al., 1987

#Writing points with rows as the coordinates
p1_t = np.array([[0,0,0], [1,0,0],[0,1,0]])
p2_t = np.array([[0,0,1], [1,0,1],[0,0,2]]) #Approx transformation is 90 degree rot over x-axis and +1 in Z axis

#Take transpose as columns should be the points
p1 = p1_t.transpose()
p2 = p2_t.transpose()

#Calculate centroids
p1_c = np.mean(p1, axis = 1).reshape((-1,1)) #If you don't put reshape then the outcome is 1D with no rows/colums and is interpeted as rowvector in next minus operation, while it should be a column vector
p2_c = np.mean(p2, axis = 1).reshape((-1,1))

#Subtract centroids
q1 = p1-p1_c
q2 = p2-p2_c

#Calculate covariance matrix

#Calculate singular value decomposition (SVD)
U, X, V_t = np.linalg.svd(H) #the SVD of linalg gives you Vt

#Calculate rotation matrix
R = np.matmul(V_t.transpose(),U.transpose())

assert np.allclose(np.linalg.det(R), 1.0), "Rotation matrix of N-point registration not 1, see paper Arun et al."

#Calculate translation matrix
T = p2_c - np.matmul(R,p1_c)

#Check result
result = T + np.matmul(R,p1)
if np.allclose(result,p2):
    print("transformation is correct!")
    print("transformation is wrong...")

I implemented this more recent algorithm: J. Cashbaugh and C. Kitts, "Automatic Calculation of a Transformation Matrix Between Two Frames," in IEEE Access, vol. 6, pp. 9614-9622, 2018, doi: 10.1109/ACCESS.2018.2799173.

Here is the Python code replicating the example in the paper. I doesn't get much more concise:

import numpy as np

a = np.array([[0.5449, 0.1955, 0.9227], [0.6862, 0.7202, 0.8004], [0.8936, 0.7218, 0.2859],
              [0.0548, 0.8778, 0.5437], [0.3037, 0.5824, 0.9848], [0.0462, 0.0707, 0.7157]])
b = np.array([[2.5144, 7.0691, 1.9754], [2.8292, 7.4454, 2.2224], [3.3518, 7.3060, 2.1198],
              [2.8392, 7.8455, 1.6229], [2.4901, 7.5449, 1.9518], [2.4273, 7.1354, 1.4349]])

a1 = np.column_stack((a,np.ones(a.shape[0])))
b1 = np.column_stack((b,np.ones(b.shape[0])))

matrixA = np.tensordot(a1,a1.T,axes=[0,1])
matrixR = np.tensordot(a1,b1.T,axes=[0,1])
matrixAinv = np.linalg.inv(matrixA)

tm = np.tensordot(matrixAinv,matrixR,axes=1).transpose() 
errors = b1 - [tm @ x for x in a1]
mean_error = np.mean([np.linalg.norm(y) for y in errors])  # 0.0109002
sum_error = np.sum([np.linalg.norm(y) for y in errors])  # 0.0654013

# print('\nA (23)\n',np.array2string(matrixA, precision=8))
# print('\n(20-22)\n',np.array2string(matrixR, precision=8))
print('\nT (24)\n',np.array2string(tm, precision=4, suppress_small=True))
print(f'Mean Error: {mean_error:.3f}')
print(f'Sum Error:  {sum_error:.3f}')
print(f'Froebenius: {np.linalg.norm(errors):.3f}')

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service and acknowledge you have read our privacy policy.

Not the answer you're looking for? Browse other questions tagged or ask your own question.