marcelcaraciolo · November 15, 2011 01:42 · jamesbondo · Dec 23, 2015
diff --git a/decision_boundary.py b/decision_boundary.py
 #Plot Boundary
 u = linspace(-1, 1.5, 50)
 v = linspace(-1, 1.5, 50)
 z = zeros(shape=(len(u), len(v)))
 for i in range(len(u)):
    for j in range(len(v)):
        z[i, j] = (map_feature(array(u[i]), array(v[j])).dot(array(theta)))

 z = z.T
 contour(u, v, z)
 title('lambda = %f' % l)
 xlabel('Microchip Test 1')
 ylabel('Microchip Test 2')
 legend(['y = 1', 'y = 0', 'Decision boundary'])
 show()


 def predict(theta, X):
    '''Predict whether the label
    is 0 or 1 using learned logistic
    regression parameters '''
    m, n = X.shape
    p = zeros(shape=(m, 1))

    h = sigmoid(X.dot(theta.T))

    for it in range(0, h.shape[0]):
        if h[it] > 0.5:
            p[it, 0] = 1
        else:
            p[it, 0] = 0

    return p


 #% Compute accuracy on our training set
 p = predict(array(theta), it)
 print 'Train Accuracy: %f' % ((y[where(p == y)].size / float(y.size)) * 100.0)
	#Plot Boundary
	u = linspace(-1, 1.5, 50)
	v = linspace(-1, 1.5, 50)
	z = zeros(shape=(len(u), len(v)))
	for i in range(len(u)):
	for j in range(len(v)):
	z[i, j] = (map_feature(array(u[i]), array(v[j])).dot(array(theta)))

	z = z.T
	contour(u, v, z)
	title('lambda = %f' % l)
	xlabel('Microchip Test 1')
	ylabel('Microchip Test 2')
	legend(['y = 1', 'y = 0', 'Decision boundary'])
	show()


	def predict(theta, X):
	'''Predict whether the label
	is 0 or 1 using learned logistic
	regression parameters '''
	m, n = X.shape
	p = zeros(shape=(m, 1))

	h = sigmoid(X.dot(theta.T))

	for it in range(0, h.shape[0]):
	if h[it] > 0.5:
	p[it, 0] = 1
	else:
	p[it, 0] = 0

	return p


	#% Compute accuracy on our training set
	p = predict(array(theta), it)
	print 'Train Accuracy: %f' % ((y[where(p == y)].size / float(y.size)) * 100.0)