Python version of the MATLAB code in this Stack Overflow post: http://stackoverflow.com/a/18648210/97160
The example shows how to determine the best-fit plane/surface (1st or higher order polynomial) over a set of three-dimensional points.
Implemented in Python + NumPy + SciPy + matplotlib.
| #!/usr/bin/evn python | |
| import numpy as np | |
| import scipy.linalg | |
| from mpl_toolkits.mplot3d import Axes3D | |
| import matplotlib.pyplot as plt | |
| # some 3-dim points | |
| mean = np.array([0.0,0.0,0.0]) | |
| cov = np.array([[1.0,-0.5,0.8], [-0.5,1.1,0.0], [0.8,0.0,1.0]]) | |
| data = np.random.multivariate_normal(mean, cov, 50) | |
| # regular grid covering the domain of the data | |
| X,Y = np.meshgrid(np.arange(-3.0, 3.0, 0.5), np.arange(-3.0, 3.0, 0.5)) | |
| XX = X.flatten() | |
| YY = Y.flatten() | |
| order = 1 # 1: linear, 2: quadratic | |
| if order == 1: | |
| # best-fit linear plane | |
| A = np.c_[data[:,0], data[:,1], np.ones(data.shape[0])] | |
| C,_,_,_ = scipy.linalg.lstsq(A, data[:,2]) # coefficients | |
| # evaluate it on grid | |
| Z = C[0]*X + C[1]*Y + C[2] | |
| # or expressed using matrix/vector product | |
| #Z = np.dot(np.c_[XX, YY, np.ones(XX.shape)], C).reshape(X.shape) | |
| elif order == 2: | |
| # best-fit quadratic curve | |
| A = np.c_[np.ones(data.shape[0]), data[:,:2], np.prod(data[:,:2], axis=1), data[:,:2]**2] | |
| C,_,_,_ = scipy.linalg.lstsq(A, data[:,2]) | |
| # evaluate it on a grid | |
| Z = np.dot(np.c_[np.ones(XX.shape), XX, YY, XX*YY, XX**2, YY**2], C).reshape(X.shape) | |
| # plot points and fitted surface | |
| fig = plt.figure() | |
| ax = fig.gca(projection='3d') | |
| ax.plot_surface(X, Y, Z, rstride=1, cstride=1, alpha=0.2) | |
| ax.scatter(data[:,0], data[:,1], data[:,2], c='r', s=50) | |
| plt.xlabel('X') | |
| plt.ylabel('Y') | |
| ax.set_zlabel('Z') | |
| ax.axis('equal') | |
| ax.axis('tight') | |
| plt.show() |
