# Similarity distance measures

Vectors like this

``````v1 = {0 0 0 1 1 0 0 1 0 1 1}
v2 = {0 1 1 1 1 1 0 1 0 1 0}
v3 = {0 0 0 0 0 0 0 0 0 0 1}
``````

Need to calculate similarity between them. Hamming distance between `v1` and `v2` is 4 and between `v1` and `v3` is also 4. But because I am interested in the groups of '1' which are together for me `v2` is far more similar to `v1` then `v3` is.

Is there any distance metrics that can capture this in the data?

The data represent occupancy of house in time, that's why it is important to me. '1' means occupied, '0' means non occupied.

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so what is the question ? –  Pradheep May 11 '13 at 11:31
sorry, already edited, if there is any distance metrics that can capture this –  user1306283 May 11 '13 at 11:32
`I am interested in the groups of '1' which are together`. Could you explain what you mean by that? 1 and 2 are more simliar because of the same amount of groups? –  Joachim Isaksson May 11 '13 at 11:57
well basically yes, 1 and 2 are more similar there is same amount of groups. Because `v2` is basically vector `v1` only with the `first group` of '1' being "wider". `V3` is almost empty vector –  user1306283 May 11 '13 at 12:16

It sounds like you need cosine similarity measure:

``````similarity = cos(v1, v2) = v1 * v2 / (|v1| |v2|)
``````

where `v1 * v2` is dot product between `v1` and `v2`:

``````v1 * v2 = v1[1]*v2[1] + v1[2]*v2[2] + ... + v1[n]*v2[n]
``````

Essentially, dot product shows how many elements in both vectors have 1 at the same position: if `v1[k] == 1` and `v2[k] == 1`, then final sum (and thus similarity) is increased, otherwise it isn't changed.

You can use dot product itself, but sometimes you would want final similarity to be normalized, e.g. be between 0 and 1. In this case you can divide dot product of `v1` and `v2` by their lengths - `|v1|` and `|v2|`. Essentially, vector length is square root of dot product of the vector with itself:

``````|v| = sqrt(v[1]*v[1] + v[2]*v[2] + ... + v[n]*v[n])
``````

Having all of these, it's easy to implement cosine distance as follows (example in Python):

``````def dot(v1, v2):
return sum(x*y for x, y in zip(v1, v2))

def length(v):
return dot(v, v)

def sim(v1, v2):
return dot(v1, v2) / (length(v1) * length(v2))
``````

Note, that I described similarity (how much two vectors are close to each other), not distance (how far they are). If you need exactly distance, you can calculate it as `dist = 1 / sim`.

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There are literally hundreds of distance functions, including distance measures for sets, such as Dice and Jaccard.

You may want to get the book "Dictionary of Distance Functions", it's pretty good.

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I think you can simply take the average of the values in each set. For example `v1` here will have an average 0.4545, average of `v2` is 0.6363 and average of `v3` is 0.0909. If the only possible values in the set are 0 and 1, then the sets with equal or nearly equal values will serve your purpose.
That's actually good idea, the problem I have though is that I have to mix the two metrics somehow together. Because vectors `0 0 1 1 ` and `1 1 0 0` would with average return both `0,5` and with my metrics `4` that all of them are displaced. Is it possible to somehow combine these two metrics that each yields half of the final value? Or is that too unpredictable? –  user1306283 May 11 '13 at 11:51
In a way I guess if the distribution below it was gaussian. But if I again take the the `0 0 1 1 ` and `1 1 0 0 ` example the std will have same results. I know how you mean it but then I would have to first cluster it make means of the clusters and then compare means and std of each cluster. But if such a complicated solution makes significant different. –  user1306283 May 11 '13 at 12:17