Gradient descent impementation python - contour lines

As a self study exercise I am trying to implement gradient descent on a linear regression problem from scratch and plot the resulting iterations on a contour plot.

My gradient descent implementation gives the correct result (tested with Sklearn) however the gradient descent plot doesn't seem to be perpendicular to the contour lines. Is this expected or did I get something wrong in my code / understanding?

Algorithm

``````import numpy as np
import pandas as pd
from matplotlib import pyplot as plt
from mpl_toolkits.mplot3d import Axes3D

def costfunction(X,y,theta):
m = np.size(y)

#Cost function in vectorized form
h = X @ theta
J = float((1./(2*m)) * (h - y).T @ (h - y));
return J;

#Initialisation of useful values
m = np.size(y)
J_history = np.zeros(num_iters)
theta_0_hist, theta_1_hist = [], [] #For plotting afterwards

for i in range(num_iters):
h = X @ theta
theta = theta - alpha * (1/m)* (X.T @ (h-y))

#Cost and intermediate values for each iteration
J_history[i] = costfunction(X,y,theta)
theta_0_hist.append(theta[0,0])
theta_1_hist.append(theta[1,0])

return theta,J_history, theta_0_hist, theta_1_hist
``````

Plot

``````#Creating the dataset (as previously)
x = np.linspace(0,1,40)
noise = 1*np.random.uniform(  size = 40)
y = np.sin(x * 1.5 * np.pi )
y_noise = (y + noise).reshape(-1,1)
X = np.vstack((np.ones(len(x)),x)).T

#Setup of meshgrid of theta values
T0, T1 = np.meshgrid(np.linspace(-1,3,100),np.linspace(-6,2,100))

#Computing the cost function for each theta combination
zs = np.array(  [costfunction(X, y_noise.reshape(-1,1),np.array([t0,t1]).reshape(-1,1))
for t0, t1 in zip(np.ravel(T0), np.ravel(T1)) ] )
#Reshaping the cost values
Z = zs.reshape(T0.shape)

theta_result,J_history, theta_0, theta_1 = gradient_descent(X,y_noise,np.array([0,-6]).reshape(-1,1),alpha = 0.3,num_iters=1000)

#Angles needed for quiver plot
anglesx = np.array(theta_0)[1:] - np.array(theta_0)[:-1]
anglesy = np.array(theta_1)[1:] - np.array(theta_1)[:-1]

%matplotlib inline
fig = plt.figure(figsize = (16,8))

#Surface plot
ax = fig.add_subplot(1, 2, 1, projection='3d')
ax.plot_surface(T0, T1, Z, rstride = 5, cstride = 5, cmap = 'jet', alpha=0.5)
ax.plot(theta_0,theta_1,J_history, marker = '*', color = 'r', alpha = .4, label = 'Gradient descent')

ax.set_xlabel('theta 0')
ax.set_ylabel('theta 1')
ax.set_zlabel('Cost function')
ax.view_init(45, 45)

#Contour plot
ax.contour(T0, T1, Z, 70, cmap = 'jet')
ax.quiver(theta_0[:-1], theta_1[:-1], anglesx, anglesy, scale_units = 'xy', angles = 'xy', scale = 1, color = 'r', alpha = .9)

plt.show()
``````

Surface and contour plots

My understanding is that the gradient descent follow contour lines perpendicularly. Is this not the case ? Thanks

• Each step in gradient descent will reduce total fitting error, true, but is not guaranteed to go directly toward a minimum. Consider the case where you physically spiral down a mountain - each step takes you down, but not straight down. If error space is "bumpy" then gradient descent can get stuck in a local error space minimum as well, that is, the steps in gradient descent are towards a lowER error but not necessarily towards the lowEST error. Commented Jun 6, 2018 at 16:40
• Fair enough, but this function is smooth and quadratic, there are no bumps and no local minima... Commented Jun 6, 2018 at 16:49
• You are correct, and again each step reduces error but the direction is not always directly straight towards the minimum, just towards a lower error. So there is "descent", but not always in a straight line. Commented Jun 6, 2018 at 17:15
• Agreed, my question is more about why the descent is not perpendicular to the contour. It is at an angle w.r.t the contour lines Commented Jun 6, 2018 at 17:31
• The gradients w.r.t total error are determined individually for each parameter, yet in each step the parameters are all changed simultaneously and not individually. This combined change might not be perpendicular to the contour lines, as you have seen here. Commented Jun 6, 2018 at 21:18