I have generated a function that replicates the matlab waterfall behaviour in matplotlib, but I don't think it is the best solution when it comes to performance.
I started from two examples in matplotlib documentation: multicolor lines and multiple lines in 3d plot. From these examples, I only saw possible to draw lines whose color varies following a given colormap according to its z value following the example, which is reshaping the input array to draw the line by segments of 2 points and setting the color of the segment to the z mean value between the 2 points.
Thus, given the input matrixes n,m
matrixes X
,Y
and Z
, the function loops over the smallest dimension between n,m
to plot each line like in the example, by 2 points segments, where the reshaping to plot by segments is done reshaping the array with the same code as the example.
def waterfall_plot(fig,ax,X,Y,Z):
'''
Make a waterfall plot
Input:
fig,ax : matplotlib figure and axes to populate
Z : n,m numpy array. Must be a 2d array even if only one line should be plotted
X,Y : n,m array
'''
# Set normalization to the same values for all plots
norm = plt.Normalize(Z.min().min(), Z.max().max())
# Check sizes to loop always over the smallest dimension
n,m = Z.shape
if n>m:
X=X.T; Y=Y.T; Z=Z.T
m,n = n,m
for j in range(n):
# reshape the X,Z into pairs
points = np.array([X[j,:], Z[j,:]]).T.reshape(-1, 1, 2)
segments = np.concatenate([points[:-1], points[1:]], axis=1)
lc = LineCollection(segments, cmap='plasma', norm=norm)
# Set the values used for colormapping
lc.set_array((Z[j,1:]+Z[j,:-1])/2)
lc.set_linewidth(2) # set linewidth a little larger to see properly the colormap variation
line = ax.add_collection3d(lc,zs=(Y[j,1:]+Y[j,:-1])/2, zdir='y') # add line to axes
fig.colorbar(lc) # add colorbar, as the normalization is the same for all, it doesent matter which of the lc objects we use
Therefore, plots looking like matlab waterfall can be easily generated with the same input matrixes as a matplotlib surface plot:
import numpy as np; import matplotlib.pyplot as plt
from matplotlib.collections import LineCollection
from mpl_toolkits.mplot3d import Axes3D
# Generate data
x = np.linspace(-2,2, 500)
y = np.linspace(-2,2, 40)
X,Y = np.meshgrid(x,y)
Z = np.sin(X**2+Y**2)
# Generate waterfall plot
fig = plt.figure()
ax = fig.add_subplot(111, projection='3d')
waterfall_plot(fig,ax,X,Y,Z)
ax.set_xlabel('X') ; ax.set_xlim3d(-2,2)
ax.set_ylabel('Y') ; ax.set_ylim3d(-2,2)
ax.set_zlabel('Z') ; ax.set_zlim3d(-1,1)
The function assumes that when generating the meshgrid, the x
array is the longest, and by default the lines have fixed y, and its the x coordinate what varies. However, if the size of the y dimension is larger, the matrixes are transposed, generating the lines with fixed x. Thus, generating the meshgrid with the sizes inverted (len(x)=40
and len(y)=500
) yields: