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Let's suppose I have a set of 2D coordinates that represent the centers of cells of a 2D regular mesh. I would like to find, for each cell in the grid, the two closest neighbors in each direction.

The problem is quite straightforward if one assigns to each cell and index defined as follows:

idx_cell = idx+N*idy

where N is the total number of cells in the grid, idx=x/dx and idy=y/dx, with x and y being the x-coordinate and the y-coordinate of a cell and dx its size.

For example, the neighboring cells for a cell with idx_cell=5 are the cells with idx_cell equal to 4,6 (for the x-axis) and 5+N,5-N (for the y-axis).

The problem that I have is that my implementation of the algorithm is quite slow for large (N>1e6) data sets.

For instance, to get the neighbors of the x-axis I do

[x[(idx_cell==idx_cell[i]-1)|(idx_cell==idx_cell[i]+1)] for i in cells]

Do you think there's a fastest way to implement this algorithm?

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I think you can speedup it by using NumPy fancy indexing. Can you post more code that create the idx, idy, cells, idx_cells,x. –  HYRY Mar 28 '13 at 10:56
    
You may also be able to make some use of scipy's cKDTree. docs.scipy.org/doc/scipy/reference/generated/… –  Ophion Mar 28 '13 at 13:33
    
Thanks I've already tried with KDTree but it's rather slow for my dataset, and also it's not convenient for a mesh. Unfortunately I won't be able to post more code because my dataset is huge. –  Matteo Mar 28 '13 at 13:35
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1 Answer 1

up vote 2 down vote accepted

You are basically reinventing the indexing scheme of a multidimensional array. It is relatively easy to code, but you can use the two functions unravel_index and ravel_multi_index to your advantage here.

If your grid is of M rows and N columns, to get the idx and idy of a single item you could do:

>>> M, N = 12, 10
>>> np.unravel_index(4, dims=(M, N))
(0, 4)

This also works if, instead of a single index, you provide an array of indices:

>>> np.unravel_index([15, 28, 32, 97], dims=(M, N))
(array([1, 2, 3, 9], dtype=int64), array([5, 8, 2, 7], dtype=int64))

So if cells has the indices of several cells you want to find neighbors to:

>>> cells = np.array([15, 28, 32, 44, 87])

You can get their neighbors as:

>>> idy, idx = np.unravel_index(cells, dims=(M, N))
>>> neigh_idx = np.vstack((idx-1, idx+1, idx, idx))
>>> neigh_idy = np.vstack((idy, idy, idy-1, idy+1))
>>> np.ravel_multi_index((neigh_idy, neigh_idx), dims=(M,N))
array([[14, 27, 31, 43, 86],
       [16, 29, 33, 45, 88],
       [ 5, 18, 22, 34, 77],
       [25, 38, 42, 54, 97]], dtype=int64)

Or, if you prefer it like that:

>>> np.ravel_multi_index((neigh_idy, neigh_idx), dims=(M,N)).T
array([[14, 16,  5, 25],
       [27, 29, 18, 38],
       [31, 33, 22, 42],
       [43, 45, 34, 54],
       [86, 88, 77, 97]], dtype=int64)

The nicest thing about going this way is that ravel_multi_index has a mode keyword argument you can use to handle items on the edges of your lattice, see the docs.

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