Are there any algorithms that will return the equation of a straight line from a set of 3D data points? I can find plenty of sources which will give the equation of a line from 2D data sets, but none in 3D.

How many points in the set? If more than 2, do you want a leastsquares fitted line? What form of equation do you want? z = f(x,y) or parametric?– Steve EmmersonFeb 19, 2010 at 17:53

I should have been more descriptive. I'd like a leastsquares parametric line. I have something like 300 3D (x,y,z) data points from a sensor that should form a line through space.– MikeFeb 20, 2010 at 17:34
2 Answers
If you are trying to predict one value from the other two, then you should use lstsq
with the a
argument as your independent variables (plus a column of 1's to estimate an intercept) and b
as your dependent variable.
If, on the other hand, you just want to get the best fitting line to the data, i.e. the line which, if you projected the data onto it, would minimize the squared distance between the real point and its projection, then what you want is the first principal component.
One way to define it is the line whose direction vector is the eigenvector of the covariance matrix corresponding to the largest eigenvalue, that passes through the mean of your data. That said, eig(cov(data))
is a really bad way to calculate it, since it does a lot of needless computation and copying and is potentially less accurate than using svd
. See below:
import numpy as np
# Generate some data that lies along a line
x = np.mgrid[2:5:120j]
y = np.mgrid[1:9:120j]
z = np.mgrid[5:3:120j]
data = np.concatenate((x[:, np.newaxis],
y[:, np.newaxis],
z[:, np.newaxis]),
axis=1)
# Perturb with some Gaussian noise
data += np.random.normal(size=data.shape) * 0.4
# Calculate the mean of the points, i.e. the 'center' of the cloud
datamean = data.mean(axis=0)
# Do an SVD on the meancentered data.
uu, dd, vv = np.linalg.svd(data  datamean)
# Now vv[0] contains the first principal component, i.e. the direction
# vector of the 'best fit' line in the least squares sense.
# Now generate some points along this best fit line, for plotting.
# I use 7, 7 since the spread of the data is roughly 14
# and we want it to have mean 0 (like the points we did
# the svd on). Also, it's a straight line, so we only need 2 points.
linepts = vv[0] * np.mgrid[7:7:2j][:, np.newaxis]
# shift by the mean to get the line in the right place
linepts += datamean
# Verify that everything looks right.
import matplotlib.pyplot as plt
import mpl_toolkits.mplot3d as m3d
ax = m3d.Axes3D(plt.figure())
ax.scatter3D(*data.T)
ax.plot3D(*linepts.T)
plt.show()
Here's what it looks like:

1

1is it possible to get a polynomial fit on this scenario...!? @dwf Feb 19, 2015 at 14:29

4Could someone explain why the principal direction is the first row of
vv
? I'm finding conflicting statements on the internet, where it usually says it should be the right singular value corresponding to the smallest singular value. That would be the last row ofvv
, no?– oarfishMay 14, 2020 at 6:00 
Calculating the SVD is quadratic in time and memory. Even for only 10k points the method takes many seconds and I get outofmemory errors. Is there a more efficient method available to compute the direction vector more efficiently?– ChrisJul 26, 2020 at 16:17

1@Chris I had to use
uu, dd, vv = np.linalg.svd(data  datamean, full_matrices=False)
to prevent running out of memory, see stackoverflow.com/q/19743525/694360– mmjDec 21, 2022 at 23:38
If your data is fairly well behaved then it should be sufficient to find the least squares sum of the component distances. Then you can find the linear regression with z independent of x and then again independent of y.
Following the documentation example:
import numpy as np
pts = np.add.accumulate(np.random.random((10,3)))
x,y,z = pts.T
# this will find the slope and xintercept of a plane
# parallel to the yaxis that best fits the data
A_xz = np.vstack((x, np.ones(len(x)))).T
m_xz, c_xz = np.linalg.lstsq(A_xz, z)[0]
# again for a plane parallel to the xaxis
A_yz = np.vstack((y, np.ones(len(y)))).T
m_yz, c_yz = np.linalg.lstsq(A_yz, z)[0]
# the intersection of those two planes and
# the function for the line would be:
# z = m_yz * y + c_yz
# z = m_xz * x + c_xz
# or:
def lin(z):
x = (z  c_xz)/m_xz
y = (z  c_yz)/m_yz
return x,y
#verifying:
from mpl_toolkits.mplot3d import Axes3D
import matplotlib.pyplot as plt
fig = plt.figure()
ax = Axes3D(fig)
zz = np.linspace(0,5)
xx,yy = lin(zz)
ax.scatter(x, y, z)
ax.plot(xx,yy,zz)
plt.savefig('test.png')
plt.show()
If you want to minimize the actual orthogonal distances from the line (orthogonal to the line) to the points in 3space (which I'm not sure is even referred to as linear regression). Then I would build a function that computes the RSS and use a scipy.optimize minimization function to solve it.

3Actually, you don't need a numerical optimizer  it's a quadratic optimization problem that is easily solved in closed form with an SVD, see my answer. :)– dwfFeb 25, 2010 at 10:55