# Plot equation showing a circle

The following formula is used to classify points from a 2-dimensional space:

``````f(x1,x2) = np.sign(x1^2+x2^2-.6)
``````

All points are in space `X = [-1,1] x [-1,1]` with a uniform probability of picking each x.

Now I would like to visualize the circle that equals:

``````0 = x1^2+x2^2-.6
``````

The values of x1 should be on the x-axis and values of x2 on the y-axis.

It must be possible but I have difficulty transforming the equation to a plot.

You can use a contour plot, as follows (based on the examples at http://matplotlib.org/examples/pylab_examples/contour_demo.html):

``````import numpy as np
import matplotlib.pyplot as plt

x = np.linspace(-1.0, 1.0, 100)
y = np.linspace(-1.0, 1.0, 100)
X, Y = np.meshgrid(x,y)
F = X**2 + Y**2 - 0.6
plt.contour(X,Y,F,[0])
plt.show()
``````

This yields the following graph

Lastly, some general statements:

1. `x^2` does not mean what you think it does in python, you have to use `x**2`.
2. `x1` and `x2` are terribly misleading (to me), especially if you state that `x2` has to be on the y-axis.
3. (Thanks to Dux) You can add `plt.gca().set_aspect('equal')` to make the figure actually look circular, by making the axis equal.
• i am slightly embarrassed that i did not think of this... Way better solution!
– Dux
Aug 19, 2015 at 10:53
• @Dux I have a similar plot in my standard recipe book, I just had to modify it a bit (my initial answer was more complex than required). The approach that you suggested will also work (if you connect your functions) and yours is easier to understand for most of the users ;) Aug 19, 2015 at 11:17
• Thanks. Seem a traight forward way of making it. Using '**' changed the output of the text when I tried to post the question. Aug 19, 2015 at 12:44
• Use `plt.gca().set_aspect('equal')` before calling `plt.show()` to achieve a circular circle...
– Dux
Aug 19, 2015 at 12:53
• Isn't that a very inefficient way to draw a circle? You need to create two grids of 10000 variables and then run a contour algorithm on it. See my answer for a different approach. Aug 19, 2015 at 14:00

The solution of @BasJansen certainly gets you there, it's either very inefficient (if you use many grid points) or inaccurate (if you use only few grid points).

You can easily draw the circle directly. Given `0 = x1**2 + x**2 - 0.6` it follows that `x2 = sqrt(0.6 - x1**2)` (as Dux stated).

But what you really want to do is to transform your cartesian coordinates to polar ones.

``````x1 = r*cos(theta)
x2 = r*sin(theta)
``````

if you use these substitions in the circle equation you will see that `r=sqrt(0.6)`.

So now you can use that for your plot:

``````import numpy as np
import matplotlib.pyplot as plt

# theta goes from 0 to 2pi
theta = np.linspace(0, 2*np.pi, 100)

# the radius of the circle
r = np.sqrt(0.6)

# compute x1 and x2
x1 = r*np.cos(theta)
x2 = r*np.sin(theta)

# create the figure
fig, ax = plt.subplots(1)
ax.plot(x1, x2)
ax.set_aspect(1)
plt.show()
``````

Result:

• Isn't this exactly as efficient as plotting `x1` and `x2` in @Bas Jansen's or my answer since you still plot on a cartesian grid and interpolation between these points will be linear instead of curved? You simply showed a maybe more elegant way of calculating the points on the circle...
– Dux
Aug 19, 2015 at 14:39
• All solutions have the same efficiency in drawing the circle. However, @Bas Jansen's answer is very inefficient in creating the data. Your solution is very similar to mine, the only difference is in my solution the points (which make up the circle) are equally spaced. You'll see the difference when you show the points (with `plt.plot(x, y, '.')` and `ax.set_aspect(1)`) Aug 19, 2015 at 16:23
• And have you tried closing the circle with your method? Aug 19, 2015 at 16:33

How about drawing x-values and calculating the corresponding y-values?

``````import numpy as np
import matplotlib.pyplot as plt

x = np.linspace(-1, 1, 100, endpoint=True)
y = np.sqrt(-x**2. + 0.6)

plt.plot(x, y)
plt.plot(x, -y)
``````

produces

This can obviously be made much nicer, but this is only for demonstration...

``````# x**2  + y**2 = r**2
r = 6
x = np.linspace(-r,r,1000)
y = np.sqrt(-x**2+r**2)
plt.plot(x, y,'b')
plt.plot(x,-y,'b')
plt.gca().set_aspect('equal')
plt.show()
``````

produces:

# Plotting a circle using complex numbers

The idea: multiplying a point by complex exponential () rotates the point on a circle

import numpy as np import matplotlib.pyplot as plt

import numpy as np import matplotlib.pyplot as plt

``````num_pts=20 # number of points on the circle
ps = np.arange(num_pts+1)
# j = np.sqrt(-1)
pts = np.exp(2j*np.pi/num_pts *(ps))

fig, ax = plt.subplots(1)
ax.plot(pts.real, pts.imag , '-o')
ax.set_aspect(1)
plt.show()
``````