# Proportional venn diagram for more than 3 sets

I have a collection of documents in MongoDB where each has one or more categories in a list. Using map reduce, I can get the details of how many documents have each unique combination of categories:

``````['cat1']               = 523
['cat2']               = 231
['cat3']               = 102
['cat4']               = 72
['cat1','cat2']        = 710
['cat1','cat3']        = 891
['cat1','cat3','cat4'] = 621 ...
``````

where the totals are for the number of documents that exact combination of categories.

I'm looking for a sensible way to present this data, and I think a venn diagram with proportional areas would be a good idea. Using the above example, the area cat1 would be 523+710+891+621, the area of the overlap between cat1 and cat3 would be 891+621, the area of overlap between cat1, cat3, cat4 would be 621 etc.

Does anyone have any tips for how I might go about implementing this? I'd preferably like to do it in Python (+Numpy/MatPlotLib) or MatLab.

• Given that a Venn diagram will not do it (see comment by ninjagecko below), and since alternatives are being suggested (see fraxel idea), I thought I would try an alternative myself, a network graph. May 30, 2012 at 10:34

## The Problem

We need to represent counts of multiple interconnected categories of object, and a Venn diagram would be unable to represent more than a trivial amount of categories and their overlap.

## A Solution

Consider each of the categories and their combinations as a node in a graph. Draw the graph such that the size of the node represents the count in each category, and the edges connect the related categories. The advantage of this approach is: multiple categories can be accommodated with ease, and this becomes a type of connected bubble chart.

## The Result ## The Code

The proposed solution uses NetworkX to create the data structure and matplotlib to draw it. If data is presented in the right format, this will scale to a large number of categories with multiple connections.

``````import networkx as nx
import matplotlib.pyplot as plt

text = '''  Node    Size
1        523
2        231
3        102
4         72
1+2      710
1+3      891
1+3+4    621'''
# this may be replaced by some appropriate output
data = text.split('\n')[1:]
data = [ d.split() for d in data ]
data = [ tuple([ d,
dict( size=int(d) )
]) for d in data]
return data

text = '''  From   To
1+2    1
1+2    2
1+3    1
1+3    3
1+3+4    1
1+3+4    3
1+3+4    4'''
# this may be replaced by some appropriate output
data = text.split('\n')[1:]
data = [ tuple( d.split() ) for d in data ]
return data

if __name__ == '__main__':
scale_factor = 5
G = nx.Graph()
node_sizes = [ n['size']*scale_factor
for n in nodes ]

nx.draw_networkx(G,
pos=nx.spring_layout(G),
node_size = node_sizes)
plt.axis('off')
plt.show()
``````

## Other Solutions

Other solutions might include: bubble charts, Voronoi diagrams, chord diagrams, and hive plots among others. None of the linked examples use Python; they are just given for illustrative purposes.

• Thanks to everyone for all the great ideas and alternatives. I think this network graph idea by gauden is the most suitable for my needs. May 30, 2012 at 14:56

I believe ninjagecko is correct and this cannot generally be represented as a diagram of intersections, unless you don't mind the diagram being in n dimensions. However, it can be represented in 2D if you have a diagram for each category showing all its intersections - and this itself can be a single diagram. So this may be a more appropriate way to represent your data. I've produced a stacked barchart to illustrate: The code:

``````cats = ['cat1','cat2','cat3','cat4']
data = {('cat1',): 523, ('cat2',): 231, ('cat3',): 102, ('cat4',): 72, ('cat1','cat2'): 710,('cat1','cat3'): 891,('cat1','cat3','cat4') : 621}

import matplotlib.pyplot as plt
import numpy as np
from random import random

colors = dict([(k,(random(),random(),random())) for k in data.keys()])
print colors
for i, cat in enumerate(sorted(cats)):
y = 0
for key, val in data.items():
if cat in key:
plt.bar(i, val, bottom=y, color=colors[key])
plt.text(i,y,' '.join(key))
y += val
plt.xticks(np.arange(len(cats))+0.4, cats )
plt.show()
``````

This is impossible in general unless, roughly, the graph of intersections is a planar graph AND you have no 4-way intersections. There is also a limit on edge lengths (unless you are willing to draw amorphous blobs to represent area); so if you insist on drawing circles, this is even more restricted.

In very simple cases, you can make a routine to draw a 3-way Venn diagram, then "add" another circle on "the other side" of the triplet. In the above case, `1,3,4` is that triplet, and `2` is the odd-one-out.

If it is possible because your data satisfies the above conditions (for some reason your graph is planar and extremely complicated), AND you use amorphous blobs, you can draw the planar graph, and slowly grow each edge to "balloon up" into an ellipsoid. You can do this in a relaxative manner: they balloon up if their intersections are lower than what they should be, and shrink if their intersections are higher than what they should be. (They actually have 2 dimensions to do this in: fattening and elongating; pick as appropriate. Elongating will push the rest of the graph, so you will have to check that this does not make things impossible, e.g. by using a physical spring-based layout.) Eventually you will probably converge on an answer, which you will have to check for accuracy.

How about a variation on Gauden's answer? Each category is a node, and weighted edges between the nodes represent the degree overlap. The more overlap, the thicker the edge.

I don't know how you'd go about scaling for proportional areas, though.

Maybe if you took a graph of the appropriate order and tesselated it. Then you could assign desired areas to each triangle and do some sort of pressure-diffusion, allowing the vertices to shift and maybe allowing some pressure to "leak" from each triangle to a neighbor belonging to the same set?

You might want to try https://github.com/icetime/pyinfor/blob/master/venn.py but I also found it on MatPlotLib too https://github.com/icetime/matplotlib/blob/master/lib/matplotlib/venn.py but I don't think it's officially accepted.