As someone already commented, a possible alternative would be the *Levenshtein distance*, also sometimes referred to as the *edit distance*.

The Levenshtein distance is a function which assigns to every pair of strings `A`

and `B`

a natural number `n`

, which represents the minimum number of operations need to transform `A`

to `B`

. The allowed operations are

- Delete a symbol from
`A`

,
- Insert a symbol into
`A`

,
- Replace a symbol in
`A`

.

Note that the edit distance is symmetric (as for any sequence of operations that transforms `A`

to `B`

) it is possible to construct an "inverted" sequence of operations which transforms `B`

to `A`

.

The Wikipedia article on the Levenshtein distance lists some useful properties.

Finally, as an example, let's transform your two vectors:

```
[10011]
// Insert 1 into position 2:
[101011]
// Insert 0 into position 5:
[1010101]
// Insert 0 into position 7:
[10101010]
```

We found a sequence of 3 operations. If we manage to prove that there are no shorter sequences, then we could conclude that the distance between `V1`

and `V2`

is 3. Well, considering that the Levenshtein distance is always *at least* the difference in size between the two strings (think about why that is), then we have our conclusion:

```
levenshtein_distance(V1,V2) == 3 // returns true!
```

Hope this helps!

`similarity`

? – Ashot Karakhanyan Feb 10 '14 at 14:28definitionof similarity as the actual algorithm to compute it. – Marko Topolnik Feb 10 '14 at 14:28