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October 28, 2011 03:57
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multivariate linear regression
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from numpy import loadtxt, zeros, ones, array, linspace, logspace, mean, std, arange | |
from mpl_toolkits.mplot3d import Axes3D | |
import matplotlib.pyplot as plt | |
from pylab import plot, show, xlabel, ylabel | |
#Evaluate the linear regression | |
def feature_normalize(X): | |
''' | |
Returns a normalized version of X where | |
the mean value of each feature is 0 and the standard deviation | |
is 1. This is often a good preprocessing step to do when | |
working with learning algorithms. | |
''' | |
mean_r = [] | |
std_r = [] | |
X_norm = X | |
n_c = X.shape[1] | |
for i in range(n_c): | |
m = mean(X[:, i]) | |
s = std(X[:, i]) | |
mean_r.append(m) | |
std_r.append(s) | |
X_norm[:, i] = (X_norm[:, i] - m) / s | |
return X_norm, mean_r, std_r | |
def compute_cost(X, y, theta): | |
''' | |
Comput cost for linear regression | |
''' | |
#Number of training samples | |
m = y.size | |
predictions = X.dot(theta) | |
sqErrors = (predictions - y) | |
J = (1.0 / (2 * m)) * sqErrors.T.dot(sqErrors) | |
return J | |
def gradient_descent(X, y, theta, alpha, num_iters): | |
''' | |
Performs gradient descent to learn theta | |
by taking num_items gradient steps with learning | |
rate alpha | |
''' | |
m = y.size | |
J_history = zeros(shape=(num_iters, 1)) | |
for i in range(num_iters): | |
predictions = X.dot(theta) | |
theta_size = theta.size | |
for it in range(theta_size): | |
temp = X[:, it] | |
temp.shape = (m, 1) | |
errors_x1 = (predictions - y) * temp | |
theta[it][0] = theta[it][0] - alpha * (1.0 / m) * errors_x1.sum() | |
J_history[i, 0] = compute_cost(X, y, theta) | |
return theta, J_history | |
#Load the dataset | |
data = loadtxt('ex1data2.txt', delimiter=',') | |
#Plot the data | |
''' | |
fig = plt.figure() | |
ax = fig.add_subplot(111, projection='3d') | |
n = 100 | |
for c, m, zl, zh in [('r', 'o', -50, -25)]: | |
xs = data[:, 0] | |
ys = data[:, 1] | |
zs = data[:, 2] | |
ax.scatter(xs, ys, zs, c=c, marker=m) | |
ax.set_xlabel('Size of the House') | |
ax.set_ylabel('Number of Bedrooms') | |
ax.set_zlabel('Price of the House') | |
plt.show() | |
''' | |
X = data[:, :2] | |
y = data[:, 2] | |
#number of training samples | |
m = y.size | |
y.shape = (m, 1) | |
#Scale features and set them to zero mean | |
x, mean_r, std_r = feature_normalize(X) | |
#Add a column of ones to X (interception data) | |
it = ones(shape=(m, 3)) | |
it[:, 1:3] = x | |
#Some gradient descent settings | |
iterations = 100 | |
alpha = 0.01 | |
#Init Theta and Run Gradient Descent | |
theta = zeros(shape=(3, 1)) | |
theta, J_history = gradient_descent(it, y, theta, alpha, iterations) | |
print theta, J_history | |
plot(arange(iterations), J_history) | |
xlabel('Iterations') | |
ylabel('Cost Function') | |
show() | |
#Predict price of a 1650 sq-ft 3 br house | |
price = array([1.0, ((1650.0 - mean_r[0]) / std_r[0]), ((3 - mean_r[1]) / std_r[1])]).dot(theta) | |
print 'Predicted price of a 1650 sq-ft, 3 br house: %f' % (price) |
I don't get the point of obtaining the size by m=y.size, and then set y.shape=(m,1).
Does anybody have any idea on what the latter does?
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You should flatten your predictions in the compute_cost function. Otherwise it returns array.