# Is it possible to plot implicit equations using Matplotlib?

I would like to plot implicit equations (of the form f(x, y)=g(x, y) eg. X^y=y^x) in Matplotlib. Is this possible?

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I don't believe there's very good support for this, but you could try something like

``````import matplotlib.pyplot
from numpy import arange
from numpy import meshgrid

delta = 0.025
xrange = arange(-5.0, 20.0, delta)
yrange = arange(-5.0, 20.0, delta)
X, Y = meshgrid(xrange,yrange)

# F is one side of the equation, G is the other
F = Y**X
G = X**Y

matplotlib.pyplot.contour(X, Y, (F - G), [0])
matplotlib.pyplot.show()
``````

See the API docs for `contour`: if the fourth argument is a sequence then it specifies which contour lines to plot. But the plot will only be as good as the resolution of your ranges, and there are certain features it may never get right, often at self-intersection points.

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This is a good solution. My solution is a more manual way of getting at the same piece of information using the same underlying concept: setting up the implicit equation as f(x, y) such that f(x, y) = 0 is equivalent to the original implicit equation and isolating its zero contour. –  Mike Graham Mar 20 '10 at 20:53

Since you've tagged this question with sympy, I will give such an example.

From the documentation: http://docs.sympy.org/modules/plotting.html.

``````from sympy import var, Plot
var('x y')
Plot(x*y**3 - y*x**3)
``````
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matplotlib does not plot equations; it plots serieses of points. You can use a tool like `scipy​.optimize` to numerically calculate y points from x values (or vice versa) of implicit equations numerically or any number of other tools as appropriate.

For example, here is an example where I plot the implicit equation `x ** 2 + x * y + y ** 2 = 10` in a certain region.

``````from functools import partial

import numpy
import scipy.optimize
import matplotlib.pyplot as pp

def z(x, y):
return x ** 2 + x * y + y ** 2 - 10

x_window = 0, 5
y_window = 0, 5

xs = []
ys = []
for x in numpy.linspace(*x_window, num=200):
try:
# A more efficient technique would use the last-found-y-value as a
# starting point
y = scipy.optimize.brentq(partial(z, x), *y_window)
except ValueError:
# Should we not be able to find a solution in this window.
pass
else:
xs.append(x)
ys.append(y)

pp.plot(xs, ys)
pp.xlim(*x_window)
pp.ylim(*y_window)
pp.show()
``````
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If you're willing to use something other than matplotlib (but still python), there's sage:

An example: http://sagenb.org/home/pub/1806

Documentation for implicit_plot

The Sage Homepage

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There is an implicit equation (and inequality) plotter in the development version of sympy. It is created as a part of GSoC and it produces the plots as matplotlib figure instances.

In the next version of sympy (0.7.2) it will be available as:

``````>>> from sympy.plotting import plot_implicit
>>> p = plot_implicit(x < sin(x)) # also creates a window with the plot
>>> the_matplotlib_axes_instance = p._backend._ax
``````

I will update this post when it is released.

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Many thanks Steve, Mike, Alex. I have gone along with Steve's solution (please see code below). My only remaining issue is that the contour plot appears behind my gridlines, as opposed to a regular plot, which I can force to the front with zorder. Any more halp greatly appreciated.

Cheers, Geddes

``````import matplotlib.pyplot as plt
from matplotlib.ticker import MultipleLocator, FormatStrFormatter
import numpy as np

fig = plt.figure(1)

# set up axis
ax.spines['left'].set_position('zero')
ax.spines['right'].set_color('none')
ax.spines['bottom'].set_position('zero')
ax.spines['top'].set_color('none')
ax.xaxis.set_ticks_position('bottom')
ax.yaxis.set_ticks_position('left')

# setup x and y ranges and precision
x = np.arange(-0.5,5.5,0.01)
y = np.arange(-0.5,5.5,0.01)

# draw a curve
line, = ax.plot(x, x**2,zorder=100)

# draw a contour
X,Y=np.meshgrid(x,y)
F=X**Y
G=Y**X
ax.contour(X,Y,(F-G),[0],zorder=100)

#set bounds
ax.set_xbound(-1,7)
ax.set_ybound(-1,7)

#produce gridlines of different colors/widths
ax.xaxis.set_minor_locator(MultipleLocator(0.2))
ax.yaxis.set_minor_locator(MultipleLocator(0.2))
ax.xaxis.grid(True,'minor',linestyle='-')
ax.yaxis.grid(True,'minor',linestyle='-')

minor_grid_lines = [tick.gridline for tick in ax.xaxis.get_minor_ticks()]
for idx,loc in enumerate(ax.xaxis.get_minorticklocs()):
if loc % 2.0 == 0:
minor_grid_lines[idx].set_color('0.3')
minor_grid_lines[idx].set_linewidth(2)
elif loc % 1.0 == 0:
minor_grid_lines[idx].set_c('0.5')
minor_grid_lines[idx].set_linewidth(1)
else:
minor_grid_lines[idx].set_c('0.7')
minor_grid_lines[idx].set_linewidth(1)

minor_grid_lines = [tick.gridline for tick in ax.yaxis.get_minor_ticks()]
for idx,loc in enumerate(ax.yaxis.get_minorticklocs()):
if loc % 2.0 == 0:
minor_grid_lines[idx].set_color('0.3')
minor_grid_lines[idx].set_linewidth(2)
elif loc % 1.0 == 0:
minor_grid_lines[idx].set_c('0.5')
minor_grid_lines[idx].set_linewidth(1)
else:
minor_grid_lines[idx].set_c('0.7')
minor_grid_lines[idx].set_linewidth(1)

plt.show()
``````
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@Geddes, it looks like support for contour respecting zorder has only recently been added to the matplotlib source. From their SVN trunk: matplotlib.svn.sourceforge.net/viewvc/… –  Mark Mar 21 '10 at 14:19