# Plotting a decision boundary separating 2 classes using Matplotlib's pyplot

I could really use a tip to help me plotting a decision boundary to separate to classes of data. I created some sample data (from a Gaussian distribution) via Python NumPy. In this case, every data point is a 2D coordinate, i.e., a 1 column vector consisting of 2 rows. E.g.,

``````[ 1
2 ]
``````

Let's assume I have 2 classes, class1 and class2, and I created 100 data points for class1 and 100 data points for class2 via the code below (assigned to the variables x1_samples and x2_samples).

``````mu_vec1 = np.array([0,0])
cov_mat1 = np.array([[2,0],[0,2]])
x1_samples = np.random.multivariate_normal(mu_vec1, cov_mat1, 100)
mu_vec1 = mu_vec1.reshape(1,2).T # to 1-col vector

mu_vec2 = np.array([1,2])
cov_mat2 = np.array([[1,0],[0,1]])
x2_samples = np.random.multivariate_normal(mu_vec2, cov_mat2, 100)
mu_vec2 = mu_vec2.reshape(1,2).T
``````

When I plot the data points for each class, it would look like this:

Now, I came up with an equation for an decision boundary to separate both classes and would like to add it to the plot. However, I am not really sure how I can plot this function:

``````def decision_boundary(x_vec, mu_vec1, mu_vec2):
g1 = (x_vec-mu_vec1).T.dot((x_vec-mu_vec1))
g2 = 2*( (x_vec-mu_vec2).T.dot((x_vec-mu_vec2)) )
return g1 - g2
``````

I would really appreciate any help!

EDIT: Intuitively (If I did my math right) I would expect the decision boundary to look somewhat like this red line when I plot the function...

• What is the `x_vec` in the `decision_boundary` function supposed to be? Are you just trying to plot a line separating the two classes? Commented Mar 10, 2014 at 9:16
• I don't have time for a full answer right know, but it sounds like you want the 0 contour of `decision_boundary`. It's easiest to just evaluate the function on a regular grid and contour the result. Hopefully that gets you pointed in the right direction! Commented Mar 10, 2014 at 14:30
• Thanks. Yes, should be a line, I uploaded an example img to the original question
– user2489252
Commented Mar 10, 2014 at 14:56

Your question is more complicated than a simple plot : you need to draw the contour which will maximize the inter-class distance. Fortunately it's a well-studied field, particularly for SVM machine learning.

The easiest method is to download the `scikit-learn` module, which provides a lot of cool methods to draw boundaries: `scikit-learn`: Support Vector Machines

Code :

``````# -*- coding: utf-8 -*-

import numpy as np
import matplotlib
from matplotlib import pyplot as plt
import scipy
from sklearn import svm

mu_vec1 = np.array([0,0])
cov_mat1 = np.array([[2,0],[0,2]])
x1_samples = np.random.multivariate_normal(mu_vec1, cov_mat1, 100)
mu_vec1 = mu_vec1.reshape(1,2).T # to 1-col vector

mu_vec2 = np.array([1,2])
cov_mat2 = np.array([[1,0],[0,1]])
x2_samples = np.random.multivariate_normal(mu_vec2, cov_mat2, 100)
mu_vec2 = mu_vec2.reshape(1,2).T

fig = plt.figure()

plt.scatter(x1_samples[:,0],x1_samples[:,1], marker='+')
plt.scatter(x2_samples[:,0],x2_samples[:,1], c= 'green', marker='o')

X = np.concatenate((x1_samples,x2_samples), axis = 0)
Y = np.array([0]*100 + [1]*100)

C = 1.0  # SVM regularization parameter
clf = svm.SVC(kernel = 'linear',  gamma=0.7, C=C )
clf.fit(X, Y)
``````

## Linear Plot

``````w = clf.coef_[0]
a = -w[0] / w[1]
xx = np.linspace(-5, 5)
yy = a * xx - (clf.intercept_[0]) / w[1]

plt.plot(xx, yy, 'k-')
``````

## MultiLinear Plot

``````C = 1.0  # SVM regularization parameter
clf = svm.SVC(kernel = 'rbf',  gamma=0.7, C=C )
clf.fit(X, Y)

h = .02  # step size in the mesh
# create a mesh to plot in
x_min, x_max = X[:, 0].min() - 1, X[:, 0].max() + 1
y_min, y_max = X[:, 1].min() - 1, X[:, 1].max() + 1
xx, yy = np.meshgrid(np.arange(x_min, x_max, h),
np.arange(y_min, y_max, h))

# Plot the decision boundary. For that, we will assign a color to each
# point in the mesh [x_min, m_max]x[y_min, y_max].
Z = clf.predict(np.c_[xx.ravel(), yy.ravel()])

# Put the result into a color plot
Z = Z.reshape(xx.shape)
plt.contour(xx, yy, Z, cmap=plt.cm.Paired)
``````

## Implementation

If you want to implement it yourself, you need to solve the following quadratic equation:

The Wikipedia article

Unfortunately, for non-linear boundaries like the one you draw, it's a difficult problem relying on a kernel trick but there isn't a clear cut solution.

• +1 for thorough answer. However, for the OP's requirements SVM might be overkill. Since the data comes from two normal distributions with different mean and covariances the decision boundary is quadratic. A QDA classifier might be sufficient (see scikit-learn.org/stable/modules/generated/sklearn.qda.QDA.html).
– MB-F
Commented Mar 12, 2014 at 15:45
• Can you please explain slope and intercept calculation from the "Linear plot" section? Commented May 17, 2022 at 12:38
• do you think, that kernel itself can not be discriminant function by its own? (even without NLP-minimization) ? -just puting yi from the difference of yi- y_pred - can we define the decision_boundary line ? or can you express it with mathematical notation/equation ? (I just have difficulty with creating minimization task from Kernel equation, but it seems that it can just be simple least-squares)... don't you think so? Commented Jun 6 at 17:58
• really, `clf.decision_function` (or `clf.predict`) from fitted clf, applied to mesh works without knowing kernel-function Commented Jun 6 at 18:43

Based on the way you've written `decision_boundary` you'll want to use the `contour` function, as Joe noted above. If you just want the boundary line, you can draw a single contour at the 0 level:

``````f, ax = plt.subplots(figsize=(7, 7))
c1, c2 = "#3366AA", "#AA3333"
ax.scatter(*x1_samples.T, c=c1, s=40)
ax.scatter(*x2_samples.T, c=c2, marker="D", s=40)
x_vec = np.linspace(*ax.get_xlim())
ax.contour(x_vec, x_vec,
decision_boundary(x_vec, mu_vec1, mu_vec2),
levels=[0], cmap="Greys_r")
``````

Which makes:

• Should the decision boundary not bend around the class with lower variance?
– MB-F
Commented Mar 13, 2014 at 7:47
• Yes, you were right. I went back and solved the equation analytically. I will post it as an answer below
– user2489252
Commented Mar 19, 2014 at 3:12

Those were some great suggestions, thanks a lot for your help! I ended up solving the equation analytically and this is the solution I ended up with (I just want to post it for future reference:

``````# 2-category classification with random 2D-sample data
# from a multivariate normal distribution

import numpy as np
from matplotlib import pyplot as plt

def decision_boundary(x_1):
""" Calculates the x_2 value for plotting the decision boundary."""
return 4 - np.sqrt(-x_1**2 + 4*x_1 + 6 + np.log(16))

# Generating a Gaussion dataset:
# creating random vectors from the multivariate normal distribution
# given mean and covariance
mu_vec1 = np.array([0,0])
cov_mat1 = np.array([[2,0],[0,2]])
x1_samples = np.random.multivariate_normal(mu_vec1, cov_mat1, 100)
mu_vec1 = mu_vec1.reshape(1,2).T # to 1-col vector

mu_vec2 = np.array([1,2])
cov_mat2 = np.array([[1,0],[0,1]])
x2_samples = np.random.multivariate_normal(mu_vec2, cov_mat2, 100)
mu_vec2 = mu_vec2.reshape(1,2).T # to 1-col vector

# Main scatter plot and plot annotation
f, ax = plt.subplots(figsize=(7, 7))
ax.scatter(x1_samples[:,0], x1_samples[:,1], marker='o', color='green', s=40, alpha=0.5)
ax.scatter(x2_samples[:,0], x2_samples[:,1], marker='^', color='blue', s=40, alpha=0.5)
plt.legend(['Class1 (w1)', 'Class2 (w2)'], loc='upper right')
plt.title('Densities of 2 classes with 25 bivariate random patterns each')
plt.ylabel('x2')
plt.xlabel('x1')
ftext = 'p(x|w1) ~ N(mu1=(0,0)^t, cov1=I)\np(x|w2) ~ N(mu2=(1,1)^t, cov2=I)'
plt.figtext(.15,.8, ftext, fontsize=11, ha='left')

# Adding decision boundary to plot
x_1 = np.arange(-5, 5, 0.1)
bound = decision_boundary(x_1)
plt.plot(x_1, bound, 'r--', lw=3)

x_vec = np.linspace(*ax.get_xlim())
x_1 = np.arange(0, 100, 0.05)

plt.show()
``````

And the code can be found here

EDIT:

I also have a convenience function for plotting decision regions for classifiers that implement a `fit` and `predict` method, e.g., the classifiers in scikit-learn, which is useful if the solution cannot be found analytically. A more detailed description how it works can be found here.

• how do you know analytically that desicion function is `4 - np.sqrt(-x_1**2 + 4*x_1 + 6 + np.log(16))` ? Commented Jan 19 at 11:57
• for such a curve can try `clf = SVC(kernel='poly')` if need to solve a Supervised problem Commented Jan 19 at 13:16

You can create your own equation for the boundary:

where you have to find the positions `x0` and `y0`, as well as the constants `ai` and `bi` for the radius equation. So, you have `2*(n+1)+2` variables. Using `scipy.optimize.leastsq` is straightforward for this type of problem.

The code attached below builds the residual for the `leastsq` penalizing the points outsize the boundary. The result for your problem, obtained with:

``````x, y = find_boundary(x2_samples[:,0], x2_samples[:,1], n)
ax.plot(x, y, '-k', lw=2.)

x, y = find_boundary(x1_samples[:,0], x1_samples[:,1], n)
ax.plot(x, y, '--k', lw=2.)
``````

using `n=1`:

using `n=2`:

usng `n=5`:

using `n=7`:

``````import numpy as np
from numpy import sin, cos, pi
from scipy.optimize import leastsq

def find_boundary(x, y, n, plot_pts=1000):

def sines(theta):
ans = np.array([sin(i*theta)  for i in range(n+1)])
return ans

def cosines(theta):
ans = np.array([cos(i*theta)  for i in range(n+1)])
return ans

def residual(params, x, y):
x0 = params[0]
y0 = params[1]
c = params[2:]

r_pts = ((x-x0)**2 + (y-y0)**2)**0.5

thetas = np.arctan2((y-y0), (x-x0))
m = np.vstack((sines(thetas), cosines(thetas))).T
r_bound = m.dot(c)

delta = r_pts - r_bound
delta[delta>0] *= 10

return delta

# initial guess for x0 and y0
x0 = x.mean()
y0 = y.mean()

params = np.zeros(2 + 2*(n+1))
params[0] = x0
params[1] = y0
params[2:] += 1000

popt, pcov = leastsq(residual, x0=params, args=(x, y),
ftol=1.e-12, xtol=1.e-12)

thetas = np.linspace(0, 2*pi, plot_pts)
m = np.vstack((sines(thetas), cosines(thetas))).T
c = np.array(popt[2:])
r_bound = m.dot(c)
x_bound = popt[0] + r_bound*cos(thetas)
y_bound = popt[1] + r_bound*sin(thetas)

return x_bound, y_bound
``````

I like the mglearn library to draw decision boundaries. Here is one example from the book "Introduction to Machine Learning with Python" by A. Mueller:

``````fig, axes = plt.subplots(1, 3, figsize=(10, 3))
for n_neighbors, ax in zip([1, 3, 9], axes):
clf = KNeighborsClassifier(n_neighbors=n_neighbors).fit(X, y)
mglearn.plots.plot_2d_separator(clf, X, fill=True, eps=0.5, ax=ax, alpha=.4)
mglearn.discrete_scatter(X[:, 0], X[:, 1], y, ax=ax)
ax.set_title("{} neighbor(s)".format(n_neighbors))
ax.set_xlabel("feature 0")
ax.set_ylabel("feature 1")
axes[0].legend(loc=3)
``````

If you want to use scikit learn, you can write your code like this:

``````import numpy as np
import pandas as pd
import matplotlib.pyplot as plt
from sklearn.linear_model import LogisticRegression

X = data[[0,1]].values
y = data[2]

# use LogisticRegression
log_reg = LogisticRegression()
log_reg.fit(X, y)

# Coefficient of the features in the decision function. (from theta 1 to theta n)
parameters = log_reg.coef_[0]
# Intercept (a.k.a. bias) added to the decision function. (theta 0)
parameter0 = log_reg.intercept_

# Plotting the decision boundary
fig = plt.figure(figsize=(10,7))
x_values = [np.min(X[:, 1] -5 ), np.max(X[:, 1] +5 )]
# calcul y values
y_values = np.dot((-1./parameters[1]), (np.dot(parameters[0],x_values) + parameter0))
colors=['red' if l==0 else 'blue' for l in y]
plt.scatter(X[:, 0], X[:, 1], label='Logistics regression', color=colors)
plt.plot(x_values, y_values, label='Decision Boundary')
plt.show()
``````

Just solved a very similar problem with a different approach (root finding) and wanted to post this alternative as answer here for future reference:

``````   def discr_func(x, y, cov_mat, mu_vec):
"""
Calculates the value of the discriminant function for a dx1 dimensional
sample given covariance matrix and mean vector.

Keyword arguments:
x_vec: A dx1 dimensional numpy array representing the sample.
cov_mat: numpy array of the covariance matrix.
mu_vec: dx1 dimensional numpy array of the sample mean.

Returns a float value as result of the discriminant function.

"""
x_vec = np.array([[x],[y]])

W_i = (-1/2) * np.linalg.inv(cov_mat)
assert(W_i.shape[0] > 1 and W_i.shape[1] > 1), 'W_i must be a matrix'

w_i = np.linalg.inv(cov_mat).dot(mu_vec)
assert(w_i.shape[0] > 1 and w_i.shape[1] == 1), 'w_i must be a column vector'

omega_i_p1 = (((-1/2) * (mu_vec).T).dot(np.linalg.inv(cov_mat))).dot(mu_vec)
omega_i_p2 = (-1/2) * np.log(np.linalg.det(cov_mat))
omega_i = omega_i_p1 - omega_i_p2
assert(omega_i.shape == (1, 1)), 'omega_i must be a scalar'

g = ((x_vec.T).dot(W_i)).dot(x_vec) + (w_i.T).dot(x_vec) + omega_i
return float(g)

#g1 = discr_func(x, y, cov_mat=cov_mat1, mu_vec=mu_vec_1)
#g2 = discr_func(x, y, cov_mat=cov_mat2, mu_vec=mu_vec_2)

x_est50 = list(np.arange(-6, 6, 0.1))
y_est50 = []
for i in x_est50:
y_est50.append(scipy.optimize.bisect(lambda y: discr_func(i, y, cov_mat=cov_est_1, mu_vec=mu_est_1) - \
discr_func(i, y, cov_mat=cov_est_2, mu_vec=mu_est_2), -10,10))
y_est50 = [float(i) for i in y_est50]
``````

Here is the result: (blue the quadratic case, red the linear case (equal variances)

Given two bi-variate normal distributions, you can use Gaussian Discriminant Analysis (GDA) to come up with a decision boundary as the difference between the log of the 2 pdf's.

Here's a way to do it using scipy multivariate_normal (the code is not optimized):

``````import numpy as np
import matplotlib.pyplot as plt
from scipy.stats import multivariate_normal
from numpy.linalg import norm
from numpy.linalg import inv
from scipy.spatial.distance import mahalanobis

def normal_scatter(mean, cov, p):

size = 100
sigma_x = cov[0,0]
sigma_y = cov[1,1]
mu_x = mean[0]
mu_y = mean[1]

x_ps, y_ps = np.random.multivariate_normal(mean, cov, size).T

x,y = np.mgrid[mu_x-3*sigma_x:mu_x+3*sigma_x:1/size, mu_y-3*sigma_y:mu_y+3*sigma_y:1/size]
grid = np.empty(x.shape + (2,))
grid[:, :, 0] = x; grid[:, :, 1] = y

z = p*multivariate_normal.pdf(grid, mean, cov)

return x_ps, y_ps, x,y,z

# Dist 1
mu_1 = np.array([1, 1])
cov_1 = .5*np.array([[1, 0], [0, 1]])
p_1 = .5
x_ps, y_ps, x,y,z = normal_scatter(mu_1, cov_1, p_1)
plt.plot(x_ps,y_ps,'x')
plt.contour(x, y, z, cmap='Blues', levels=3)

# Dist 2
mu_2 = np.array([2, 1])
#cov_2 = np.array([[2, -1], [-1, 1]])
cov_2 = cov_1
p_2 = .5
x_ps, y_ps, x,y,z = normal_scatter(mu_2, cov_2, p_2)
plt.plot(x_ps,y_ps,'.')
plt.contour(x, y, z, cmap='Oranges', levels=3)

# Decision Boundary
X = np.empty(x.shape + (2,))
X[:, :, 0] = x; X[:, :, 1] = y
g = np.log(p_1*multivariate_normal.pdf(X, mu_1, cov_1)) - np.log(p_2*multivariate_normal.pdf(X, mu_2, cov_2))

plt.contour(x, y, g, [0])

plt.grid()
plt.axhline(y=0, color='k')
plt.axvline(x=0, color='k')
plt.plot([mu_1[0], mu_2[0]], [mu_1[1], mu_2[1]], 'k')
plt.show()
``````

If p_1 != p_2, then you get non-linear boundary. The decision boundary is given by `g` above.

Then to plot the decision hyper-plane (line in 2D), you need to evaluate `g` for a 2D mesh, then get the contour which will give a separating line.

You can also assume to have equal co-variance matrices for both distributions, which will give a linear decision boundary. In this case, you can replace the calculation of `g` in the above code with the following:

``````W = inv(cov_1).dot(mu_1-mu_2)

x_0 = 1/2*(mu_1+mu_2) - cov_1.dot(np.log(p_1/p_2)).dot((mu_1-mu_2)/mahalanobis(mu_1, mu_2, cov_1))
X = np.empty(x.shape + (2,))
X[:, :, 0] = x; X[:, :, 1] = y

g = (X-x_0).dot(W)
``````

i use this method from this book python-machine-learning-2nd.pdf URL

``````from matplotlib.colors import ListedColormap
import matplotlib.pyplot as plt

def plot_decision_regions(X, y, classifier, test_idx=None, resolution=0.02):

# setup marker generator and color map
markers = ('s', 'x', 'o', '^', 'v')
colors = ('red', 'blue', 'lightgreen', 'gray', 'cyan')
cmap = ListedColormap(colors[:len(np.unique(y))])

# plot the decision surface
x1_min, x1_max = X[:, 0].min() - 1, X[:, 0].max() + 1
x2_min, x2_max = X[:, 1].min() - 1, X[:, 1].max() + 1
xx1, xx2 = np.meshgrid(np.arange(x1_min, x1_max, resolution),
np.arange(x2_min, x2_max, resolution))
Z = classifier.predict(np.array([xx1.ravel(), xx2.ravel()]).T)
Z = Z.reshape(xx1.shape)
plt.contourf(xx1, xx2, Z, alpha=0.3, cmap=cmap)
plt.xlim(xx1.min(), xx1.max())
plt.ylim(xx2.min(), xx2.max())

for idx, cl in enumerate(np.unique(y)):
plt.scatter(x=X[y == cl, 0],
y=X[y == cl, 1],
alpha=0.8,
c=colors[idx],
marker=markers[idx],
label=cl,
edgecolor='black')

# highlight test samples
if test_idx:
# plot all samples
X_test, y_test = X[test_idx, :], y[test_idx]

plt.scatter(X_test[:, 0],
X_test[:, 1],
c='',
edgecolor='black',
alpha=1.0,
linewidth=1,
marker='o',
s=100,
label='test set')
``````

I know this question has been answered in a very thorough way analytically. I just wanted to share a possible 'hack' to the problem. It is unwieldy but gets the job done.

Start by building a mesh grid of the 2d area and then based on the classifier just build a class map of the entire space. Subsequently detect changes in the decision made row-wise and store the edges points in a list and scatter plot the points.

``````def disc(x):   # returns the class of the point based on location x = [x,y]
temp = 0.5  + 0.5*np.sign(disc0(x)-disc1(x))
# disc0() and disc1() are the discriminant functions of the respective classes
return 0*temp + 1*(1-temp)

num = 200
a = np.linspace(-4,4,num)
b = np.linspace(-6,6,num)
X,Y = np.meshgrid(a,b)

def decColor(x,y):
temp = np.zeros((num,num))
print x.shape, np.size(x,axis=0)
for l in range(num):
for m in range(num):
p = np.array([x[l,m],y[l,m]])
#print p
temp[l,m] = disc(p)
return temp
boundColorMap = decColor(X,Y)

group = 0
boundary = []
for x in range(num):
group = boundColorMap[x,0]
for y in range(num):
if boundColorMap[x,y]!=group:
boundary.append([X[x,y],Y[x,y]])
group = boundColorMap[x,y]
boundary = np.array(boundary)
``````

Sample Decision Boundary for a simple bivariate gaussian classifier

Since version 1.1, sklearn has a function for this: https://scikit-learn.org/stable/modules/generated/sklearn.inspection.DecisionBoundaryDisplay.html#sklearn.inspection.DecisionBoundaryDisplay

if you do not have current from sklearn.inspection import DecisionBoundaryDisplay - for previous versions of `sklearn` can use SVC.decision_function

``````import numpy as np
import matplotlib
from matplotlib import pyplot as plt
import scipy
from sklearn import svm

from sklearn.datasets import make_classification
X, Y = make_classification(200, n_features=2, n_informative=2, n_redundant=0, random_state=42)

C = 1.0  # SVM regularization parameter
clf = svm.SVC(kernel = 'rbf',  gamma=0.7, C=C )
clf.fit(X, Y)

###################
h=0.02
fig = plt.figure()
##plt.figure(figsize=(1, 1))
# create a mesh to plot in
x_min, x_max = X[:, 0].min() - 1, X[:, 0].max() + 1
y_min, y_max = X[:, 1].min() - 1, X[:, 1].max() + 1
xx, yy = np.meshgrid(np.arange(x_min, x_max, h), np.arange(y_min, y_max, h))

# evaluate decision function !!!
Z = clf.decision_function(np.c_[xx.ravel(), yy.ravel()])
Z = Z.reshape(xx.shape)

# visualize decision function
##plt.contour(xx, yy, Z, cmap=plt.cm.Greys)
plt.pcolormesh(xx, yy, -Z, cmap=plt.cm.Blues)
plt.scatter(X[:,0], X[:,1],  c=Y,  marker='o',  cmap=plt.cm.binary, edgecolors="k")
plt.show()
``````