47

Two and three dimensional data can be viewed relatively straight-forwardly using traditional plot types. Even with four dimensional data, we can often find a way to display the data. Dimensions above four, though, become increasingly difficult to display. Fortunately, parallel coordinates plots provide a mechanism for viewing results with higher dimensions.

Example Parallel Coordinates Plot from Wikipedia

Several plotting packages provide parallel coordinates plots, such as Matlab, R, VTK type 1 and VTK type 2, but I don't see how to create one using Matplotlib.

  1. Is there a built-in parallel coordinates plot in Matplotlib? I certainly don't see one in the gallery.
  2. If there is no built-in-type, is it possible to build a parallel coordinates plot using standard features of Matplotlib?

Edit:

Based on the answer provided by Zhenya below, I developed the following generalization that supports an arbitrary number of axes. Following the plot style of the example I posted in the original question above, each axis gets its own scale. I accomplished this by normalizing the data at each axis point and making the axes have a range of 0 to 1. I then go back and apply labels to each tick-mark that give the correct value at that intercept.

The function works by accepting an iterable of data sets. Each data set is considered a set of points where each point lies on a different axis. The example in __main__ grabs random numbers for each axis in two sets of 30 lines. The lines are random within ranges that cause clustering of lines; a behavior I wanted to verify.

This solution isn't as good as a built-in solution since you have odd mouse behavior and I'm faking the data ranges through labels, but until Matplotlib adds a built-in solution, it's acceptable.

#!/usr/bin/python
import matplotlib.pyplot as plt
import matplotlib.ticker as ticker

def parallel_coordinates(data_sets, style=None):

    dims = len(data_sets[0])
    x    = range(dims)
    fig, axes = plt.subplots(1, dims-1, sharey=False)

    if style is None:
        style = ['r-']*len(data_sets)

    # Calculate the limits on the data
    min_max_range = list()
    for m in zip(*data_sets):
        mn = min(m)
        mx = max(m)
        if mn == mx:
            mn -= 0.5
            mx = mn + 1.
        r  = float(mx - mn)
        min_max_range.append((mn, mx, r))

    # Normalize the data sets
    norm_data_sets = list()
    for ds in data_sets:
        nds = [(value - min_max_range[dimension][0]) / 
                min_max_range[dimension][2] 
                for dimension,value in enumerate(ds)]
        norm_data_sets.append(nds)
    data_sets = norm_data_sets

    # Plot the datasets on all the subplots
    for i, ax in enumerate(axes):
        for dsi, d in enumerate(data_sets):
            ax.plot(x, d, style[dsi])
        ax.set_xlim([x[i], x[i+1]])

    # Set the x axis ticks 
    for dimension, (axx,xx) in enumerate(zip(axes, x[:-1])):
        axx.xaxis.set_major_locator(ticker.FixedLocator([xx]))
        ticks = len(axx.get_yticklabels())
        labels = list()
        step = min_max_range[dimension][2] / (ticks - 1)
        mn   = min_max_range[dimension][0]
        for i in xrange(ticks):
            v = mn + i*step
            labels.append('%4.2f' % v)
        axx.set_yticklabels(labels)


    # Move the final axis' ticks to the right-hand side
    axx = plt.twinx(axes[-1])
    dimension += 1
    axx.xaxis.set_major_locator(ticker.FixedLocator([x[-2], x[-1]]))
    ticks = len(axx.get_yticklabels())
    step = min_max_range[dimension][2] / (ticks - 1)
    mn   = min_max_range[dimension][0]
    labels = ['%4.2f' % (mn + i*step) for i in xrange(ticks)]
    axx.set_yticklabels(labels)

    # Stack the subplots 
    plt.subplots_adjust(wspace=0)

    return plt


if __name__ == '__main__':
    import random
    base  = [0,   0,  5,   5,  0]
    scale = [1.5, 2., 1.0, 2., 2.]
    data = [[base[x] + random.uniform(0., 1.)*scale[x]
            for x in xrange(5)] for y in xrange(30)]
    colors = ['r'] * 30

    base  = [3,   6,  0,   1,  3]
    scale = [1.5, 2., 2.5, 2., 2.]
    data.extend([[base[x] + random.uniform(0., 1.)*scale[x]
                 for x in xrange(5)] for y in xrange(30)])
    colors.extend(['b'] * 30)

    parallel_coordinates(data, style=colors).show()

Edit 2:

Here is an example of what comes out of the above code when plotting Fisher's Iris data. It isn't quite as nice as the reference image from Wikipedia, but it is passable if all you have is Matplotlib and you need multi-dimensional plots.

Example result of parallel coordinates plot from this answer

  • +1 Excellent question! I'm sure that the answer to #2 is yes, but I don't know how easy or difficult it is. – ptomato Nov 22 '11 at 17:00
  • 1
    getting the lines will be straightforward. Getting the axes may be more difficult. – Simon Bergot Nov 22 '11 at 17:26
  • Nice function. I tried it with my discrete data set, but the labels on the axes are floats on strange positions like in your plot, why is it like that? – Varlor Nov 27 '17 at 12:55
16

I'm sure there is a better way of doing it, but here's a quick-and-dirty one (a really dirty one):

#!/usr/bin/python
import numpy as np
import matplotlib.pyplot as plt
import matplotlib.ticker as ticker

#vectors to plot: 4D for this example
y1=[1,2.3,8.0,2.5]
y2=[1.5,1.7,2.2,2.9]

x=[1,2,3,8] # spines

fig,(ax,ax2,ax3) = plt.subplots(1, 3, sharey=False)

# plot the same on all the subplots
ax.plot(x,y1,'r-', x,y2,'b-')
ax2.plot(x,y1,'r-', x,y2,'b-')
ax3.plot(x,y1,'r-', x,y2,'b-')

# now zoom in each of the subplots 
ax.set_xlim([ x[0],x[1]])
ax2.set_xlim([ x[1],x[2]])
ax3.set_xlim([ x[2],x[3]])

# set the x axis ticks 
for axx,xx in zip([ax,ax2,ax3],x[:-1]):
  axx.xaxis.set_major_locator(ticker.FixedLocator([xx]))
ax3.xaxis.set_major_locator(ticker.FixedLocator([x[-2],x[-1]]))  # the last one

# EDIT: add the labels to the rightmost spine
for tick in ax3.yaxis.get_major_ticks():
  tick.label2On=True

# stack the subplots together
plt.subplots_adjust(wspace=0)

plt.show()

This is essentially based on a (much nicer) one by Joe Kingon, Python/Matplotlib - Is there a way to make a discontinuous axis?. You might also want to have a look at the other answer to the same question.

In this example I don't even attempt at scaling the vertical scales, since it depends on what exactly you are trying to achieve.

EDIT: Here is the resultenter image description here

  • @Simon: yes, you need dim-1 subplots – ev-br Nov 23 '11 at 13:39
  • Nice approach. On my display, the last axis doesn't have any units on it. How would you add the units to the last axis? I have two other questions, but they may go beyond the scope of this question. 1) Can you label the axis? 2) The 'move' tool on interactive plots allows each axis to be moved independent of the others. Can you constrain them to all move together and only in the y-dimension? – Nathan Nov 23 '11 at 14:54
  • @Nathan: I've edited the answer to add tick marks to the rightmost axis. There are various ways you can label the axes --- see e.g. this one, stackoverflow.com/questions/6236238/…. With your second question, I've no idea, so if you make it a separate question, there's a chance somebody more knowledgeable will be able to see it. – ev-br Nov 23 '11 at 15:55
  • @Zhenya This has been an awesome starting point! I'm working on finishing up the fine details and will be posting the fully fleshed out solution in the next couple of days. My hang up right now is dealing with the vertical axes. To match the figure I cited in the question, each axis has to have an independent scale. The sub-plot method, though, has an independent scale across an entire sub-plot. To get axis-dependent scales, I've normalized the data on each axis and then applied custom labels to each axis. I also need twinx for the last sub-plot so the last two axis are independent. – Nathan Nov 25 '11 at 15:33
46

pandas has a parallel coordinates wrapper:

import pandas
import matplotlib.pyplot as plt
from pandas.tools.plotting import parallel_coordinates

data = pandas.read_csv(r'C:\Python27\Lib\site-packages\pandas\tests\data\iris.csv', sep=',')
parallel_coordinates(data, 'Name')
plt.show()

screenshot

Source code, how they made it: plotting.py#L494

  • 3
    Can each axis be scaled independently? If I have mutliple axis with wildly different scales (say 0 to 1 and 0 to 1e6), uniform axis scaling results in unreadable plots. – Nathan Oct 23 '13 at 21:41
  • 2
    Is there a way to turn it into an interactive tool? – Dror Sep 1 '14 at 11:31
  • 1
    Scaling each axis could be hacked by just dividing out some constant from your data and making note of the constant in the legend, for example. – gradi3nt Sep 17 '16 at 20:18
  • 1
    @gradi3nt That doesn't really work in practice, though, because, at least in the image above, only one of the axes has units on it. You'd also need to somehow denote the units on the other axes to make scaling a practical solution. – Nathan Sep 20 '16 at 21:25
  • 1
    from pandas.tools.plotting import parallel_coordinates is now deprecated, the deprecation warning recommends using from pandas.plotting import parallel_coordinates instead (still works exactly the same, though). – Graipher Apr 5 '18 at 9:57
11

When using pandas (like suggested by theta), there is no way to scale the axes independently.

The reason you can't find the different vertical axes is because there aren't any. Our parallel coordinates is "faking" the other two axes by just drawing a vertical line and some labels.

https://github.com/pydata/pandas/issues/7083#issuecomment-74253671

0

Best example I've seen thus far is this one

https://python.g-node.org/python-summerschool-2013/_media/wiki/datavis/olympics_vis.py

See the normalised_coordinates function. Not super fast, but works from what I've tried.

normalised_coordinates(['VAL_1', 'VAL_2', 'VAL_3'], np.array([[1230.23, 1500000, 12453.03], [930.23, 140000, 12453.03], [130.23, 120000, 1243.03]]), [1, 2, 1])
0

Still far from perfect but it works and is relatively short:

import numpy as np

import matplotlib.pyplot as plt

def plot_parallel(data,labels):

    data=np.array(data)
    x=list(range(len(data[0])))
    fig, axis = plt.subplots(1, len(data[0])-1, sharey=False)


    for d in data:
        for i, a in enumerate(axis):
            temp=d[i:i+2].copy()
            temp[1]=(temp[1]-np.min(data[:,i+1]))*(np.max(data[:,i])-np.min(data[:,i]))/(np.max(data[:,i+1])-np.min(data[:,i+1]))+np.min(data[:,i])
            a.plot(x[i:i+2], temp)


    for i, a in enumerate(axis):
        a.set_xlim([x[i], x[i+1]])
        a.set_xticks([x[i], x[i+1]])
        a.set_xticklabels([labels[i], labels[i+1]], minor=False, rotation=45)
        a.set_ylim([np.min(data[:,i]),np.max(data[:,i])])


    plt.subplots_adjust(wspace=0)

    plt.show()

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