# How to plot complex numbers (Argand Diagram) using matplotlib

I'd like to create an Argand Diagram from a set of complex numbers using matplotlib.

Are there any pre-built functions to help me do this?

Can anyone recommend an approach?

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I'm not sure exactly what you're after here...you have a set of complex numbers, and want to map them to the plane by using their real part as the x coordinate and the imaginary part as y?

If so you can get the real part of any python imaginary number with `number.real` and the imaginary part with `number.imag`. If you're using numpy, it also provides a set of helper functions numpy.real and numpy.imag etc. which work on numpy arrays.

So for instance if you had an array of complex numbers stored something like this:

``````In [13]: a = n.arange(5) + 1j*n.arange(6,11)

In [14]: a
Out[14]: array([ 0. +6.j,  1. +7.j,  2. +8.j,  3. +9.j,  4.+10.j])
``````

...you can just do

``````In [15]: fig,ax = subplots()

In [16]: ax.scatter(a.real,a.imag)
``````

This plots dots on an argand diagram for each point.

edit: For the plotting part, you must of course have imported matplotlib.pyplot via `from matplotlib.pyplot import *` or (as I did) use the ipython shell in pylab mode.

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Try to avoid `import *`: it's much more readable and less confusing if you don't import in the current name space and do something like `import matplotlib.pyplot as plt` and then `plt.`. Plus this avoids you possible name clashes – Francesco Montesano Jul 3 '13 at 11:45

To follow up @inclement's answer; the following function produces an argand plot that is centred around 0,0 and scaled to the maximum absolute value in the set of complex numbers.

I used the plot function and specified solid lines from (0,0). These can be removed by replacing `ro-` with `ro`.

``````def argand(a):
import matplotlib.pyplot as plt
import numpy as np
for x in range(len(a)):
plt.plot([0,a[x].real],[0,a[x].imag],'ro-',label='python')
limit=np.max(np.ceil(np.absolute(a))) # set limits for axis
plt.xlim((-limit,limit))
plt.ylim((-limit,limit))
plt.ylabel('Imaginary')
plt.xlabel('Real')
plt.show()
``````

For example:

``````>>> a = n.arange(5) + 1j*n.arange(6,11)
>>> from argand import argand
>>> argand(a)
``````

produces:

EDIT:

I have just realised there is also a `polar` plot function:

``````for x in a:
plt.polar([0,angle(x)],[0,abs(x)],marker='o')
``````

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