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I use matplotlib to plot a scatter chart:

enter image description here

And label the bubble using a transparent box according to the tip at matplotlib: how to annotate point on a scatter automatically placed arrow?

Here is the code:

if show_annote:
    for i in range(len(x)):
        annote_text = annotes[i][0][0]  # STK_ID
        ax.annotate(annote_text, xy=(x[i], y[i]), xytext=(-10,3),
            textcoords='offset points', ha='center', va='bottom',
            bbox=dict(boxstyle='round,pad=0.2', fc='yellow', alpha=0.2),

and the resulting plot: enter image description here

But there is still room for improvement to reduce overlap (for instance the label box offset is fixed as (-10,3)). Are there algorithms that can:

  1. dynamically change the offset of label box according to the crowdedness of its neighbourhood
  2. dynamically place the label box remotely and add an arrow line beween bubble and label box
  3. somewhat change the label orientation
  4. label_box overlapping bubble is better than label_box overlapping label_box?

I just want to make the chart easy for human eyes to comprehand, so some overlap is OK, not as rigid a constraint as suggests. And the bubble quantity within the chart is less than 150 most of the time.

I find the so called Force-based label placement is quite interesting. I don't know if there is any python code/package available to implement the algorithm.

I am not an academic guy and not looking for an optimum solution, and my python codes need to label many many charts, so the the speed/memory is in the scope of consideration.

I am looking for a quick and effective solution. Any help (code,algorithm,tips,thoughts) on this subject? Thanks.

share|improve this question
I bet you could do something cool with networkx and it's layout engine. – tcaswell Apr 7 '13 at 5:50

1 Answer 1

It is a little rough around the edges (I can't quite figure out how to scale the relative strengths of the spring network vs the repulsive force, and the bounding box is a bit screwed up), but this is a decent start:

import networkx as nx

N = 15
scatter_data = rand(3, N)

data_nodes = []
init_pos = {}
for j, b in enumerate(scatter_data.T):
    x, y, _ = b
    data_str = 'data_{0}'.format(j)
    ano_str = 'ano_{0}'.format(j)
    G.add_edge(data_str, ano_str)
    init_pos[data_str] = (x, y)
    init_pos[ano_str] = (x, y)

pos = nx.spring_layout(G, pos=init_pos, fixed=data_nodes)
ax = gca()
ax.scatter(scatter_data[0], scatter_data[1], c=scatter_data[2], s=scatter_data[2]*150)

for j in range(N):
    data_str = 'data_{0}'.format(j)
    ano_str = 'ano_{0}'.format(j)
                xy=pos[data_str], xycoords='data',
                xytext=pos[ano_str], textcoords='data',

all_pos = np.vstack(pos.values())
mins = np.min(all_pos, 0)
maxs = np.max(all_pos, 0)

ax.set_xlim([mins[0], maxs[0]])
ax.set_ylim([mins[1], maxs[1]])


sample image

How well it works depends a bit on how your data is clustered.

share|improve this answer
Yes, this is a decent start, looks improving the display result. I will take a look at networkx. Thanks, – bigbug Apr 7 '13 at 10:48

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