# matplotlib 2D plot from x,y,z values

I am a Python beginner.

I have a list of X values

``````x_list = [-1,2,10,3]
``````

and I have a list of Y values

``````y_list = [3,-3,4,7]
``````

I then have a Z value for each couple. Schematically, this works like that:

``````X   Y    Z
-1  3    5
2   -3   1
10  4    2.5
3   7    4.5
``````

and the Z values are stored in `z_list = [5,1,2.5,4.5]`. I need to get a 2D plot with the X values on the X axis, the Y values on the Y axis, and for each couple the Z value, represented by an intensity map. This is what I have tried, unsuccessfully:

``````X, Y = np.meshgrid(x_list, y_list)
fig, ax = plt.subplots()
extent = [x_list.min(), x_list.max(), y_list.min(), y_list.max()]
im=plt.imshow(z_list, extent=extent, aspect = 'auto')
plt.colorbar(im)
plt.show()
``````

How to get this done correctly?

The problem is that `imshow(z_list, ...)` will expect `z_list` to be an `(n,m)` type array, basically a grid of values. To use the imshow function, you need to have Z values for each grid point, which you can accomplish by collecting more data or interpolating.

Here is an example, using your data with linear interpolation:

``````from scipy.interpolate import interp2d

# f will be a function with two arguments (x and y coordinates),
# but those can be array_like structures too, in which case the
# result will be a matrix representing the values in the grid
# specified by those arguments
f = interp2d(x_list,y_list,z_list,kind="linear")

x_coords = np.arange(min(x_list),max(x_list)+1)
y_coords = np.arange(min(y_list),max(y_list)+1)
Z = f(x_coords,y_coords)

fig = plt.imshow(Z,
extent=[min(x_list),max(x_list),min(y_list),max(y_list)],
origin="lower")

# Show the positions of the sample points, just to have some reference
fig.axes.set_autoscale_on(False)
plt.scatter(x_list,y_list,400,facecolors='none')
``````

You can see that it displays the correct values at your sample points (specified by `x_list` and `y_list`, shown by the semicircles), but it has much bigger variation at other places, due to the nature of the interpolation and the small number of sample points.

Here is one way of doing it:

``````import matplotlib.pyplot as plt
import numpy as np
from matplotlib.colors import LogNorm

x_list = np.array([-1,2,10,3])
y_list = np.array([3,-3,4,7])
z_list = np.array([5,1,2.5,4.5])

N = int(len(z_list)**.5)
z = z_list.reshape(N, N)
plt.imshow(z, extent=(np.amin(x_list), np.amax(x_list), np.amin(y_list), np.amax(y_list)), norm=LogNorm(), aspect = 'auto')
plt.colorbar()
plt.show()
``````

I followed this link: How to plot a density map in python?

I am not as sharp when it comes to use python and matplotlib, but I wanted to share my experience. My trouble is that my X and Y datasets were not the same length, as well as being relatively heavy datasets, which turned out to be dysfunctional using any of the methods mentioned above. Therefore, I used the heavy, inelegant method with a loop to populate the Z matrix. It takes 2-3 minutes on my laptop, but it does exactly what I want.

``````"""
@author: Benoit
"""
import matplotlib.pyplot as plt
plt.style.use('seaborn-white')
import numpy as np
import matplotlib.cm as cm

data = np.genfromtxt('MY_DATA_FILE.csv', delimiter=';', skip_header = 1)

#list of X, Y and Z
x_list = data[:,0]
y_list = data[:,1]
z_list = data[:,2]

length = np.size(x_list)

#list of X and Y values (np.unique removes redundancies)
N_x = np.unique(x_list)
N_y = np.unique(y_list)
X, Y = np.meshgrid(N_x,N_y)

length_x = np.size(N_x)
length_y = np.size(N_y)

#define empty intensity matrix
Z = np.full((length_x, length_y), 0)

#the f function will chase the Z values corresponding
# to a given x and y value

def f(x, y):
for i in range(0, length):
if (x_list[i] == x) and (y_list[i] == y):
return z_list[i]

#a loop will now populate the Z matrix
for i in range(0, length_x - 1):
for j in range(0, length_y - 1):
Z[i,j] = f(N_x[i], N_y[j])

#and then comes the plot, with the colour-blind-friendly viridis colourmap
plt.contourf(X, Y, np.transpose(Z), 20, origin = 'lower', cmap=cm.viridis, alpha = 1.0);
cbar = plt.colorbar()
cbar.set_label('intensity (a.u.)')

#optional countour lines:
"""contours = plt.contour(X, Y, np.transpose(Z), colors='black');
plt.clabel(contours, inline=True, fontsize=8)
"""
plt.xlabel('X_TITLE (unit)')
plt.ylabel('Y_TITLE (unit)')
plt.axis(aspect='image')

plt.show()
plt.savefig('TYPE_YOUR_NAME.png', DPI = 600)
``````

diffraction 2D example