Python 3D polynomial surface fit, order dependent

I am currently working with astronomical data among which I have comet images. I would like to remove the background sky gradient in these images due to the time of capture (twilight). The first program I developed to do so took user selected points from Matplotlib's "ginput" (x,y) pulled the data for each coordinate (z) and then gridded the data in a new array with SciPy's "griddata."

Since the background is assumed to vary only slightly, I would like to fit a 3d low order polynomial to this set of (x,y,z) points. However, the "griddata" does not allow for an input order:

``````griddata(points,values, (dimension_x,dimension_y), method='nearest/linear/cubic')
``````

Any ideas on another function that may be used or a method for developing a leas-squares fit that will allow me to control the order?

-

Griddata uses a spline fitting. A 3rd order spline is not the same thing as a 3rd order polynomial (instead, it's a different 3rd order polynomial at every point).

If you just want to fit a 2D, 3rd order polynomial to your data, then do something like the following to estimate the 16 coefficients using all of your data points.

``````import itertools
import numpy as np
import matplotlib.pyplot as plt

def main():
# Generate Data...
numdata = 100
x = np.random.random(numdata)
y = np.random.random(numdata)
z = x**2 + y**2 + 3*x**3 + y + np.random.random(numdata)

# Fit a 3rd order, 2d polynomial
m = polyfit2d(x,y,z)

# Evaluate it on a grid...
nx, ny = 20, 20
xx, yy = np.meshgrid(np.linspace(x.min(), x.max(), nx),
np.linspace(y.min(), y.max(), ny))
zz = polyval2d(xx, yy, m)

# Plot
plt.imshow(zz, extent=(x.min(), y.max(), x.max(), y.min()))
plt.scatter(x, y, c=z)
plt.show()

def polyfit2d(x, y, z, order=3):
ncols = (order + 1)**2
G = np.zeros((x.size, ncols))
ij = itertools.product(range(order+1), range(order+1))
for k, (i,j) in enumerate(ij):
G[:,k] = x**i * y**j
m, _, _, _ = np.linalg.lstsq(G, z)
return m

def polyval2d(x, y, m):
order = int(np.sqrt(len(m))) - 1
ij = itertools.product(range(order+1), range(order+1))
z = np.zeros_like(x)
for a, (i,j) in zip(m, ij):
z += a * x**i * y**j
return z

main()
``````

-
This is a very elegant solution to the problem. I have used your suggested code to fit an elliptic paraboloid with a slight modification I want to share. I was interested in fitting only linear solutions in the form `z = a*(x-x0)**2 + b*(y-y0)**2 + c`. The full code to my changes can be seen here. – regeirk Nov 16 '11 at 12:24

The following implementation of `polyfit2d` uses the available numpy methods `numpy.polynomial.polynomial.polyvander2d` and `numpy.polynomial.polynomial.polyval2d`

``````#!/usr/bin/env python3

import unittest

def polyfit2d(x, y, f, deg):
from numpy.polynomial import polynomial
import numpy as np
x = np.asarray(x)
y = np.asarray(y)
f = np.asarray(f)
deg = np.asarray(deg)
vander = polynomial.polyvander2d(x, y, deg)
vander = vander.reshape((-1,vander.shape[-1]))
f = f.reshape((vander.shape[0],))
c = np.linalg.lstsq(vander, f)[0]
return c.reshape(deg+1)

class MyTest(unittest.TestCase):

def setUp(self):
return self

def test_1(self):
self._test_fit(
[-1,2,3],
[ 4,5,6],
[[1,2,3],[4,5,6],[7,8,9]],
[2,2])

def test_2(self):
self._test_fit(
[-1,2],
[ 4,5],
[[1,2],[4,5]],
[1,1])

def test_3(self):
self._test_fit(
[-1,2,3],
[ 4,5],
[[1,2],[4,5],[7,8]],
[2,1])

def test_4(self):
self._test_fit(
[-1,2,3],
[ 4,5],
[[1,2],[4,5],[0,0]],
[2,1])

def test_5(self):
self._test_fit(
[-1,2,3],
[ 4,5],
[[1,2],[4,5],[0,0]],
[1,1])

def _test_fit(self, x, y, c, deg):
from numpy.polynomial import polynomial
import numpy as np
X = np.array(np.meshgrid(x,y))
f = polynomial.polyval2d(X[0], X[1], c)
c1 = polyfit2d(X[0], X[1], f, deg)
np.testing.assert_allclose(c1,
np.asarray(c)[:deg[0]+1,:deg[1]+1],
atol=1e-12)

unittest.main()
``````
-