# Efficient matching of two arrays (how to use KDTree)

I have two 2d arrays, `obs1` and `obs2`. They represent two independent measurement series, and both have dim0 = 2, and slightly different dim1, say `obs1.shape = (2, 250000)`, and `obs2.shape = (2, 250050)`. `obs1[0]` and `obs2[0]` signify time, and `obs1[1]` and `obs2[1]` signify some spatial coordinate. Both arrays are (more or less) sorted by time. The times and coordinates should be identical between the two measurement series, but in reality they aren't. Also, not each measurement from `obs1` has a corresponding value in `obs2` and vice-versa. Another problem is that there might be a slight offset in the times.

I'm looking for an efficient algorithm to associate the best matching value from `obs2` to each measurement in `obs1`. Currently, I do it like this:

``````define dt = some_maximum_time_difference
define dx = 3
j = 0
i = 0
matchresults = np.empty(obs1.shape[1])
for j in obs1.shape[1]:
while obs1[0, j] - obs2[0, j] < dt:
i += 1
matchresults[j] = i - dx + argmin(abs(obs1[1, i] - obs2[1, i-dx:i+dx+1]))
``````

This yields good results. However, it is extremely slow, running in a loop.

I would be very thankful for ideas on how to improve this algorithm speed-wise, e.g. using KDtree or something similar.

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Can you please expand a bit on ```first_obs2_index_with_time_difference_lessthan_delta_t resulting_i = i + argmin(abs(obs1[1, i] - obs2[1, i-delta_x:i+delta_x+1])```? Assuming that you are not performing another loop here, I don't believe KDTrees would speed things up too much. –  Miky Dinescu Mar 20 at 13:58
@MikyDinescu thanks for your question; I updated the algorithm in the original post. –  andreas-h Mar 20 at 14:06
can you post a bit of data, and your expected results? –  Jeff Mar 20 at 17:57
I was wondering of anybody replied to you. Thanks for posting more details but unfortunately it's still unclear to me how your current algo. works.. I'm not a python developer so maybe somebody else will chime in. I would suggest though to present your algorithm in pseudo code instead. Or maybe ask on a more CS stack exchange.. –  Miky Dinescu Mar 21 at 1:24
@MikyDinescu could you take a look in the answer below? I guess it solves your problem... –  Saullo Castro Apr 30 at 8:31

This solution works very well if you have enough memory to create the meshgrid and to store the sorted indexes. It does not use the KDTree, though.

``````import numpy as np

obs1 = np.array([[ 0.,  1.,  2.,  3.,  4.,  5.],
[10., 11., 12., 13., 14., 15.]])

# the input obs2 may be unsorted with time

obs2 = np.array([[ 0.09,  1.9,  1.1,  1.5,  4.2,  3.1,  5.1],
[    3,    4,  3.1,   10,   20,    2,    3]])

# the following demands memory

om1,om2 = np.meshgrid(obs1[0],obs2[0])

# calculating the distance (faster than Eucledean distance, avoids sqrt())
dist = (om1-om2)**2

# performing the sorting and storing the indexes (also demands memory)
# sorting for axis=1 can be used to find the best match from obs1
# for the points of obs2

indexes = np.argsort( dist, axis=0 )

# The following should be used to collect the results from obs2
# giving the desired closest points

ans = obs2[:, indexes[0]]

# array([[  0.09,   1.1 ,   1.9 ,   3.1 ,   4.2 ,   5.1 ],
#        [     3 ,  3.1 ,     4 ,     2 ,    20 ,     3 ]])
``````

Now you can apply your `dt` criterion for each element in `ans`.

If you have to do it piecewise due to memory issues, you can iterate over `obs1` and do the same as above, but working with sub-elements of `obs1`.

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