# SQL efficient nearest neighbour query

I'm having trouble coming up with an efficient SQL query to handle the following situation:

Assume we have a table with two columns

``````groupId : int
value : float
``````

The table is huge (several million rows). There are a varying amount of "values" per "groupId" - say something between 100 and 50.000. All float values are greater or equal to zero but are otherwise unbounded.

For a given groupId the query should return all other groups sorted by decreasing similarity where "similar" is defined as minimum euclidian distance between all possible pairs of 30 values in two groups.

That definition of similarity is what kills me. I think for calculating similarity as defined above the naiive algorithm is O(n^2). Now I'm looking for ideas to either redefine "similarity" or an efficient implementation of the above. I could imagine a solution involving a k-nearest neighbour, something like PostGis geometrical nearest neighbours or maybe a largest common subsequence algorithm (although I'd need a "fuzzy" implementation of the latter because "values" will hardly ever compare exactly equal).

We are currently on mySQL in case it matters.

cheers,

``````Sören
``````
-
"There are a varying amount of "values" per "groupId" - say something between 100 and 50.000" and "all possible pairs of 30 values in two groups" confuses me. Can you clarify, or maybe give an idea of how the naive approach would work? –  tpdi Apr 6 '09 at 18:42
How many groups are you typically dealing with? –  Tom H. Apr 6 '09 at 19:52
Danbruc (the first answer below) describes the problem much better than I did. Maybe his analysis will clarify the problem? We currenlty have ~500 groups and ~1.800.000 values. We do hope to scale this to several 100.000 groups though. The current setup is just a small testcase. –  BuschnicK Apr 7 '09 at 7:55
When you say the "minimum euclidian distance between all possible pairs of 30 values", do you mean {10, 100} is closer to {10, 9999} (because they are 0 apart), or closer to {20, 90} (because the minimum total distance is 10 + 10 = 20) –  FryGuy Apr 7 '09 at 8:50
dist((10,100),(10,9999)) = sqrt((10-10)^2 + (9999-100)^2) = large dist((10,100),(20,90)) = sqrt((10-20)^2 + (100-90)^2) = smaller –  BuschnicK Apr 7 '09 at 10:10

Could you verify that I got the question right?

Your table represents vectors identified by the groupId. Every vector has a dimension of something between 100 and 50,000, but there is no order defined on the dimension. That is a vector from the table is actually a representative of equivalence class.

Now you define the similarity of two equivalence classes as the minimum Euclidian distance of the projections of any two representative of the equivalence classes to the subspace of the first 30 dimensions.

Examples for projection to two dimensions:

``````A = <1, 2, 3, 4>
B = <5, 6, 7, 8, 9, 10>
``````

A represents the following equivalence class of vectors.

``````<1, 2, 3, 4>    <2, 1, 2, 3>    <3, 1, 2, 4>    <4, 1, 2, 3>
<1, 2, 4, 4>    <2, 1, 3, 2>    <3, 1, 4, 2>    <4, 1, 3, 2>
<1, 3, 2, 4>    <2, 3, 1, 4>    <3, 2, 1, 4>    <4, 2, 1, 3>
<1, 3, 4, 2>    <2, 3, 4, 1>    <3, 2, 4, 1>    <4, 2, 3, 1>
<1, 4, 2, 2>    <2, 4, 1, 3>    <3, 4, 1, 2>    <4, 3, 1, 2>
<1, 4, 3, 2>    <2, 4, 3, 1>    <3, 4, 2, 1>    <4, 3, 2, 1>
``````

The projection of all representative of this equivalence class to the first two dimensions yields.

``````<1, 2>    <1, 3>    <1, 4>
<2, 1>    <2, 3>    <2, 4>
<3, 1>    <3, 2>    <3, 4>
<4, 1>    <4, 2>    <4, 3>
``````

B represents a equivalence class with 720 elements. The projection to the first two dimensions yields 30 elements.

``````< 5, 6>    < 5, 7>    < 5, 8>    < 5, 9>    < 5, 10>
< 6, 5>    < 6, 7>    < 6, 8>    < 6, 9>    < 6, 10>
< 7, 5>    < 7, 6>    < 7, 8>    < 7, 9>    < 7, 10>
< 8, 5>    < 8, 6>    < 8, 7>    < 8, 9>    < 8, 10>
< 9, 5>    < 9, 6>    < 9, 7>    < 9, 8>    < 9, 10>
<10, 5>    <10, 6>    <10, 7>    <10, 8>    <10,  9>
``````

So the distance of A and B is the square root of 8, because this is the minimum distance of two vectors from the projections. For example <3, 4> and <5, 6> yield this distance.

So, am I right with my understanding of the problem?

A really naive algorithm for n vectors with m components each would have to calculate (n - 1) distances. For each distance the algorithm would calculate the distances of m! / (m - 30)! projection for each vector. So for 100 dimensions (your lower bound) there are 2.65*10^32 possible projection for a vector. This requires to calculate about 7*10^64 distances between projections and finding the minimum to find the distance of two vectors. And then repeat this n times.

I hope that I misunderstood you or made a mistake. Else this sounds something between really challenging and not feasible.

Something I thought about is ordering the vector components and trying to match them. Using Manhattan distance - if possible - may help to simplify the solution.

-
Yes, you understood the problem perfectly and explained it much better than I did. Ordering the vectors is what I have been thinking about as well - hence my mention of LCS (longest common subsequence). I'll look into whether Manhattan distance might be of use for us. –  BuschnicK Apr 7 '09 at 7:57

Here are some nice approximations:

You could calculate the center of mass of each group and then compare based on the distance of each groups center of mass.

Another way you could do it is by hash the coordinates of each row and rows that hash to the same location are considered similar and thus the two groups similarity are updated.

Is the information constantly being updated and if so at what interval. How up to date and how accurate does it need to be?

-
Center of mass in 1 dimension? Wouldn't that just be median or mean? Or do you mean center of mass of all possible 30 value vector permutations? Hashing would basically mean quantizing all values right? I.e. we'd snap all values to a grid? –  BuschnicK Apr 7 '09 at 7:59
Existing information is never updated - only new groups added. Say 100 per day. Accuracy would be nice but is not critical. This whole setup is a preprocessing step. The idea is to get the most likely "matches" from the database and proceed to test those with a much more expensive stand alone tool. –  BuschnicK Apr 7 '09 at 8:01
I didn't read the first answer which clears things up. I am not sure my answer is any good given this. –  fuzzy-waffle Apr 7 '09 at 8:49

The naive version would be something like this: (not run through query analyser)

``````select groupid, min(distance) as mindist
from
(select other.groupid as groupid,
min(abs(other.value - us.value)) as distance
from g us
join g other on other.groupid != us.groupid
where us.groupid = ?)
order by mindist
group by groupid
``````

Then, to take advantage of indicies:

``````select groupid, min(abs(value - usvalue)) as mindist
from
(select other.groupid as groupid,
max(other.value) as value,
us.value as usvalue
from g us
join g other on other.groupid != us.groupid and other.value <= us.value
where us.groupid = ?

union

select other.groupid as groupid,
min(other.value) as value,
us.value as usvalue
from g us
join g other on other.groupid != us.groupid and other.value >= us.value
where us.groupid = ?)
order by mindist
group by groupid
``````

This should hopefully allow mysql to use an index to quickly find the nearest neighbors on the join.

There might be errors in this, but hopefully this line of thought will help.

-
Thanks FryGuy. This is pretty much what we have tried but it doesn't scale at all. I'll experiment with variations of the above and post results. –  BuschnicK Apr 7 '09 at 8:02
do you have indicies on both groupid and value? –  FryGuy Apr 7 '09 at 8:46
yes. mySQL "explain" (the query execution plan) looks as good as it'll get as far as I can tell. –  BuschnicK Apr 7 '09 at 10:07
This SQL statement might use some coordinates multiple times. Is this allowed or desired? For <1, 2, 3, 4> and <5, 100, 100, 100> the distance calculation will use the first coordinate 5 four times. –  Daniel Brückner Apr 7 '09 at 11:00
Well, I misread the question. This query will not answer your question, but order by the minimum distance chosen from the choices of all distance from group1 to group2 (not the sum of minimum distances). Should I remove this answer? –  FryGuy Apr 8 '09 at 2:16