# Determining and storing Voronoi Cell Adjacency

I will be working with a set of thousands of points. I can implement or use existing implementations of Fortunes Algorithm to produce the Voronoi diagram of the points, but my application also requires me to know adjacency with respect to each Voronoi Cell.

More specifically, for any Voronoi cell I need to know the cells that are adjacent to this. At this point I'm not to concerned with output or storage method as I can likely massage an implementation to work in my favor.

Is anyone aware of an algorithm, or better yet aware of an implemented algorithm that can accomplish cell adjacency determination? The work I will be doing is in python, but anything would be great as I can easily translate the code.

Thanks!

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A possible algorithm is available here which uses a Linear Programming approach.

PuLP can generate MPS or LP files and call GLPK, COIN, CPLEX, and GUROBI to solve linear problems.

PuLP is an LP modeler written in Python and could be used to model this linear program in Python and then solve using GLPK.

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You could do this in a few different ways.

If you just have access to the Voronoi diagram, you could look for shared edge segments between cells. If you find two cells that share a Voronoi edge segment it means that they are adjacent. An efficient way to build up the adjacency information for the whole data-set is to build a hash table of edges by scanning the list of Voronoi cells.

``````for (all cells in voronoi diagram)
for (all edges in current cell)
if (matching edge found in hash table)
// the matching edge segment to the hash table
else
// push current edge segment onto hash table and mark with
// current cell index
endif
endfor
endfor
``````

There are many good existing packages that can be used to calculate the Voronoi diagram/Delaunay triangulation for a point-set. Since it's a computationally expensive and numerically sensitive operation I'd recommend sticking with an existing library. The Triangle and QHull packages are widely used.

Hope this helps.

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Although this is an old question, I was searching for same and thought that the answer might still be helpful for somebody. One can use `Delaunay` from `scipy` module.

``````from scipy.spatial import Delaunay
from collections import defaultdict
import itertools

points=[[0.0, 0.0], [0.0, 1.0], [0.2, 0.5], [0.3, 0.6], [0.4, 0.5], [0.6, 0.3], [0.6, 0.5], [1.0, 0.0], [1.0, 1.0]]
tri = Delaunay(points)
neiList=defaultdict(set)
for p in tri.vertices:
for i,j in itertools.combinations(p,2):

for key in sorted(neiList.iterkeys()):
print("%d:%s" % (key,','.join([str(i) for i in neiList[key]])))

0:1,2,5,7
1:0,8,2,3
2:0,1,3,4,5
3:8,1,2,4,6
4:2,3,5,6
5:0,2,4,6,7
6:8,3,4,5,7
7:8,0,5,6
8:1,3,6,7

# This is for visualization
from scipy.spatial import Voronoi, voronoi_plot_2d
import matplotlib.pyplot as plt
vor = Voronoi(points)
voronoi_plot_2d(vor)
for i,p in enumerate(x):
plt.text(p[0], p[1], '#%d' % i, ha='center')
plt.show()
``````

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