# Making a non-overlapping bubble chart in Matplotlib (circle packing)

I am currently trying to make a bubble chart in Matplotlib where the bubbles do not overlap, so packing the circles/bubbles in the chart, approximately like this.

What I thought might work:

• Plot the first data-point using x = 1, y = 1
• Randomly plotting the other data-points by calculating the radius of the bubble given the scalar value as to avoid overlapping

But I have not been able to really implement it and could not find anything on this.

• I don't think there is a function specific for this in matplotlib. If you use scatter plots they will overlap. You will probably have to calculate the radius and position the bubbles accordingly. – Hugo Sadok Sep 9 '17 at 14:43

The following would be a brute-force approach.
You can first place all circles on a grid, with a gridspacing as large as twice the maximum radius of any of the circles.

Then you let the circles do a random walk and check in each step if the "potential energy" of the bunch of cicles has become smaller and if the positions obtained are valid (i.e. no overlaps).

``````if (e < self.E and self.isvalid(i)):
``````

As a "potential" we can simply use a square radial function.

``````self.p = lambda x,y: np.sum((x**2+y**2)**2)
``````

The code:

``````import numpy as np
import matplotlib.pyplot as plt

# create 10 circles with different radii
r = np.random.randint(5,15, size=10)

class C():
def __init__(self,r):
self.N = len(r)
self.x = np.ones((self.N,3))
self.x[:,2] = r
maxstep = 2*self.x[:,2].max()
length = np.ceil(np.sqrt(self.N))
grid = np.arange(0,length*maxstep,maxstep)
gx,gy = np.meshgrid(grid,grid)
self.x[:,0] = gx.flatten()[:self.N]
self.x[:,1] = gy.flatten()[:self.N]
self.x[:,:2] = self.x[:,:2] - np.mean(self.x[:,:2], axis=0)

self.step = self.x[:,2].min()
self.p = lambda x,y: np.sum((x**2+y**2)**2)
self.E = self.energy()
self.iter = 1.

def minimize(self):
while self.iter < 1000*self.N:
for i in range(self.N):
rand = np.random.randn(2)*self.step/self.iter
self.x[i,:2] += rand
e = self.energy()
if (e < self.E and self.isvalid(i)):
self.E = e
self.iter = 1.
else:
self.x[i,:2] -= rand
self.iter += 1.

def energy(self):
return self.p(self.x[:,0], self.x[:,1])

def distance(self,x1,x2):
return np.sqrt((x1[0]-x2[0])**2+(x1[1]-x2[1])**2)-x1[2]-x2[2]

def isvalid(self, i):
for j in range(self.N):
if i!=j:
if self.distance(self.x[i,:], self.x[j,:]) < 0:
return False
return True

def plot(self, ax):
for i in range(self.N):
circ = plt.Circle(self.x[i,:2],self.x[i,2] )

c = C(r)

fig, ax = plt.subplots(subplot_kw=dict(aspect="equal"))
ax.axis("off")

c.minimize()

c.plot(ax)
ax.relim()
ax.autoscale_view()
plt.show()
``````

Because of the random walk nature of this, finding the solution will take a little time (~10 seconds in this case); you may of course play with the parameters (mainly the number of steps `1000*self.N` until a solution is fixed) and see what suits your needs.

• This worked like a charm, thanks a lot! – rongon Sep 12 '17 at 14:51