Skip to main content

Smooth data fitting in N dimensions

Project description

smoothfit

PyPi Version PyPI pyversions GitHub stars PyPi downloads

Discord

Given experimental data, it is often desirable to produce a function whose values match the data to some degree. This package implements a robust approach to data fitting based on the minimization problem

\|\lambda\Delta f\|^2_{L^2(\Omega)} + \sum_i (f(x_i) - y_i)^2 \to\min

(A similar idea is used in for data smoothing in signal processing; see, e.g., section 8.3 in this document.)

Unlike polynomial regression or Gauss-Newton, smoothfit makes no assumptions about the function other than that it is smooth.

The generality of the approach makes it suitable for function whose domain is multidimensional, too.

Pics or it didn't happen

Runge's example

Runge's example function is a tough nut for classical polynomial regression.

If there is no noise in the input data, the parameter lmbda can be chosen quite small such that all data points are approximated well. Note that there are no oscillations in the output function u.

import matplotlib.pyplot as plt
import numpy as np
import smoothfit

a = -1.5
b = +1.5

# plot original function
x = np.linspace(a, b, 201)
plt.plot(x, 1 / (1 + 25 * x ** 2), "-", color="0.8", label="1 / (1 + 25 * x**2)")

# sample points
x0 = np.linspace(-1.0, 1.0, 21)
y0 = 1 / (1 + 25 * x0 ** 2)
plt.plot(x0, y0, "xk")

# smoothfit
basis, coeffs = smoothfit.fit1d(x0, y0, a, b, 1000, degree=1, lmbda=1.0e-6)
plt.plot(basis.mesh.p[0], coeffs[basis.nodal_dofs[0]], "-", label="smooth fit")

plt.ylim(-0.1)
plt.grid()
plt.show()

Runge's example with noise

If the data is noisy, lmbda needs to be chosen more carefully. If too small, the approximation tries to resolve all data points, resulting in many small oscillations. If it's chosen too large, no details are resolved, not even those of the underlying data.

import matplotlib.pyplot as plt
import numpy as np
import smoothfit

a = -1.5
b = +1.5

# plot original function
x = np.linspace(a, b, 201)
plt.plot(x, 1 / (1 + 25 * x ** 2), "-", color="0.8", label="1 / (1 + 25 * x**2)")

# 21 sample points
rng = np.random.default_rng(0)
n = 51
x0 = np.linspace(-1.0, 1.0, n)
y0 = 1 / (1 + 25 * x0 ** 2)
y0 += 1.0e-1 * (2 * rng.random(n) - 1)
plt.plot(x0, y0, "xk")

lmbda = 5.0e-2
basis, coeffs = smoothfit.fit1d(x0, y0, a, b, 1000, degree=1, lmbda=lmbda)
plt.plot(basis.mesh.p[0], coeffs[basis.nodal_dofs[0]], "-", label="smooth fit")

plt.grid()
plt.show()

Few samples

import numpy as np
import smoothfit

x0 = np.array([0.038, 0.194, 0.425, 0.626, 1.253, 2.500, 3.740])
y0 = np.array([0.050, 0.127, 0.094, 0.2122, 0.2729, 0.2665, 0.3317])
u = smoothfit.fit1d(x0, y0, 0, 4, 1000, degree=1, lmbda=1.0)

Some noisy example data taken from Wikipedia.

A two-dimensional example

import meshzoo
import numpy as np
import smoothfit

n = 200
rng = np.random.default_rng(123)
x0 = rng.random((n, 2)) - 0.5
y0 = np.cos(np.pi * np.sqrt(x0.T[0] ** 2 + x0.T[1] ** 2))

# create a triangle mesh for the square
points, cells = meshzoo.rectangle_tri(
    np.linspace(-1.0, 1.0, 32), np.linspace(-1.0, 1.0, 32)
)

basis, u = smoothfit.fit(x0, y0, points, cells, lmbda=1.0e-4, solver="dense-direct")

# Write the function to a file
basis.mesh.save("out.vtu", point_data={"u": u})

This example approximates a function from R2 to R (without noise in the samples). Note that the absence of noise the data allows us to pick a rather small lmbda such that all sample points are approximated well.

Comparison with other approaches

Polynomial fitting/regression

The classical approach to data fitting is polynomial regression. Polynomials are chosen because they are very simple, can be evaluated quickly, and can be made to fit any function very closely.

There are, however, some fundamental problems:

This above plot highlights the problem with oscillations.

Fourier smoothing

One approach to data fitting with smoothing is to create a function with all data points, and simply cut off the high frequencies after Fourier transformation.

This approach is fast, but only works for evenly spaced samples.

For equidistant curve fitting there is nothing else that could compete with the Fourier series. -- Cornelius Lanczos

import matplotlib.pyplot as plt
import numpy as np


rng = np.random.default_rng(0)

# original function
x0 = np.linspace(-1.0, 1.0, 1000)
y0 = 1 / (1 + 25 * x0 ** 2)
plt.plot(x0, y0, color="k", alpha=0.2)

# create sample points
n = 51
x1 = np.linspace(-1.0, 1.0, n)  # only works if samples are evenly spaced
y1 = 1 / (1 + 25 * x1 ** 2) + 1.0e-1 * (2 * rng.random(x1.shape[0]) - 1)
plt.plot(x1, y1, "xk")

# Cut off the high frequencies in the transformed space and transform back
X = np.fft.rfft(y1)
X[5:] = 0.0
y2 = np.fft.irfft(X, n)
#
plt.plot(x1, y2, "-", label="5 lowest frequencies")

plt.grid()
plt.show()

Project details


Download files

Download the file for your platform. If you're not sure which to choose, learn more about installing packages.

Source Distributions

No source distribution files available for this release.See tutorial on generating distribution archives.

Built Distribution

smoothfit-0.4.1-py3-none-any.whl (15.8 kB view details)

Uploaded Python 3

File details

Details for the file smoothfit-0.4.1-py3-none-any.whl.

File metadata

  • Download URL: smoothfit-0.4.1-py3-none-any.whl
  • Upload date:
  • Size: 15.8 kB
  • Tags: Python 3
  • Uploaded using Trusted Publishing? No
  • Uploaded via: twine/4.0.1 CPython/3.11.2

File hashes

Hashes for smoothfit-0.4.1-py3-none-any.whl
Algorithm Hash digest
SHA256 928946c3b80791e28d3a26d0314c4ba20f747b63c94a0470f6fef7ea72873943
MD5 fe2d2fbe393792b3d5e333968df22ee4
BLAKE2b-256 f848a0e53c2f8a97f2189ba90596c26b33afbab40479258a9d21e3764aad094e

See more details on using hashes here.

Supported by

AWS AWS Cloud computing and Security Sponsor Datadog Datadog Monitoring Fastly Fastly CDN Google Google Download Analytics Microsoft Microsoft PSF Sponsor Pingdom Pingdom Monitoring Sentry Sentry Error logging StatusPage StatusPage Status page