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There are different methods to calculate distance between two vectors of the same length: Euclidean, Manhattan, Hamming ...

I'm wondering about any method that would calculate distance between vectors of different length.

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What do your vectors contains ? (Bits, floats, ...) ? Can't you fill them with 0 and apply one of the same-length-vectors distances ? –  Scharron Feb 16 '12 at 16:32
    
@Scharron, I think you are confusing the dimension of a vector with the length (norm) of a vector. OP did not mention anywhere that the number of components in one vector differs from the number of components in another vector. –  ardnew Feb 16 '12 at 20:06
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@ardnew You're right in pure mathematics. But the way the question is expressed, I assumed he talked about "computer science" length, meaning the number of elements in a vector. Else, he would have no problem computing the distance of different-length vectors. –  Scharron Feb 17 '12 at 9:26
    
As you commented, I meant vectors with different number of elements on them, –  user1155073 Feb 19 '12 at 20:54
    
is there a way to normalize them to the same number of elements? –  user1155073 Feb 19 '12 at 20:55
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1 Answer

The Euclidean distance formula finds the distance between any two points in Euclidean space.

A point in Euclidean space is also called a Euclidean vector.

You can use the Euclidean distance formula to calculate the distance between vectors of two different lengths.

For vectors of different dimension, the same principle applies.

Suppose a vector of lower dimension also exists in the higher dimensional space. You can then set all of the missing components in the lower dimensional vector to 0 so that both vectors have the same dimension. You would then use any of the mentioned distance formulas for computing the distance.

For example, consider a 2-dimensional vector A in with components (a1,a2), and a 3-dimensional vector B in with components (b1,b2,b3).

To express A in , you would set its components to (a1,a2,0). Then, the Euclidean distance d between A and B can be found using the formula:

d² = (b1 - a1)² + (b2 - a2)² + (b3 - 0)²

d = sqrt((b1 - a1)² + (b2 - a2)² + b3²)

For your particular case, the components will be either 0 or 1, so all differences will be -1, 0, or 1. The squared differences will then only be 0 or 1.

If you're using integers or individual bits to represent the components, you can use simple bitwise operations instead of some arithmetic (^ means XOR or exclusive or):

d = sqrt(b1 ^ a1 + b2 ^ a2 + ... + b(n-1) ^ a(n-1) + b(n) ^ a(n))

And we're assuming the trailing components of A are 0, so the final formula will be:

d = sqrt(b1 ^ a1 + b2 ^ a2 + ... + b(n-1) + b(n))
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In the beginning, it makes sense. But now, after a thinking a while, to set the missing value of the missing dimension to zero, could cause problems, if you use the Euclidean to calculate fingerprint matching for locationing. In your example...imagine the vector A contains (0,0) and the vektor B contains (0,0,0) AND a Vektor C contains (0,0,0), than the Euclidean would result in a distance calculation of zero, for both distances. But A is far more away to B as C is. –  JacksOnF1re Apr 30 at 21:51
    
@JacksOnF1re im not sure i follow. in your example, why should the distance from A to B be different than the distance from B to C? –  ardnew Apr 30 at 23:21
    
My explanation is a little bit poor. What I mean, if you calculate the distance with euclidean, the distance between A and B is the same like B and C. But that is the Problem! A to B should return a higher distance, because of the missing dimension. That can cause problems (I guess), if it comes to calculations for localization. mathematically correct, but limited usefull for programming issues. Sorry for my english. –  JacksOnF1re Apr 30 at 23:40
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