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So it is clear with NetworkX that they use an algorithm in n^2 time to generate a random geometric graph. They say there is a faster algorithm possible with the use of K-D Trees. My question is how would one go about attempting to implement the K-D Tree version of this algorithm? I am not familiar with this data structure, nor would I call myself a python expert. Just trying to figure this out. All help is appreciated, thanks!

    def random_geometric_graph(n, radius, dim=2, pos=None):
        G=nx.Graph()
        G.name="Random Geometric Graph"
        G.add_nodes_from(range(n)) 
        if pos is None:
            # random positions
            for n in G:
                G.node[n]['pos']=[random.random() for i in range(0,dim)]
        else:
            nx.set_node_attributes(G,'pos',pos)
        # connect nodes within "radius" of each other
        # n^2 algorithm, could use a k-d tree implementation
        nodes = G.nodes(data=True)
        while nodes:
            u,du = nodes.pop()
            pu = du['pos']
            for v,dv in nodes:
                pv = dv['pos']
                d = sum(((a-b)**2 for a,b in zip(pu,pv)))
                if d <= radius**2:
                    G.add_edge(u,v)
    return G
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2  
can you fix up the indentation in your code, it is difficult to read and I don't want to guess at the indent levels. –  tcaswell Dec 10 '12 at 15:39
    
scipy has a KD-tree implementation docs.scipy.org/doc/scipy/reference/generated/… –  tcaswell Dec 10 '12 at 15:41

1 Answer 1

up vote 2 down vote accepted

Here is a way that uses the scipy KD-tree implementation mentioned by @tcaswell above.

import numpy as np
from scipy import spatial
import networkx as nx
import matplotlib.pyplot as plt
nnodes = 100
r = 0.15
positions =  np.random.rand(nnodes,2)
kdtree = spatial.KDTree(positions)
pairs = kdtree.query_pairs(r)
G = nx.Graph()
G.add_nodes_from(range(nnodes))
G.add_edges_from(list(pairs))
pos = dict(zip(range(nnodes),positions))
nx.draw(G,pos)
plt.show()
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