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I have records of data, where each record is a various-length array of integers in strictly increasing order. Here are some examples:

record_1 : 1,2,3,4,5,6,8,9,10
record_2 : 5,30,31,32,33,34,35,36
record_3 : 10,11,12,19,20

I want to measure (or give score) of contiguity on each array, i.e. how "close" every adjacent elements of the array. Currently I'm using sum of difference of each adjacent array element (pseudo-code):

for i=2 to length(A) do
    sum_diff += A[i] - A[i-1]
score = (length(A) - 1) / sum_diff

So for a perfectly-continuous array (example: 1,2,3,4,5) the score will be 1 (highest score).

But problem arises for a data that is contiguous but contains a "jump", for example record_2 above, there is a "jump" from 5 to 30.

For above data example, the scores using my algorithm are:

record_1 : 0.89
record_2 : 0.23
record_3 : 0.4

It gives score to record_2 lower than record_3, but we can intuitively see that record_2 should has higher score than record_3 because record_2 is contiguous except the jump from 5 to 30.

So, does anyone have an idea on how should I modify my algorithm to give better contiguity measurement? Thanks before.

share|improve this question
Assuming you mean sum_diff += A[i] - A[i-1], and that your monotonicity guarantee holds, note that your given algorithm is equivalent to score = (length(A) - 1) / (A[length(A)-1] - A[0]), i.e. that the values in the middle of the series are completely irrelevant to the overall score. –  Weeble Feb 16 '12 at 13:52
I can't intuitively see that record_2 should have a higher score. One break of sequence in 8 sounds better than one in 5. –  Jonas Elfström Feb 16 '12 at 13:56
@Weeble : sorry for the mistake, edited my question, thanks. –  Muhammad Abrar Feb 16 '12 at 13:57
I don't think it's possible to give a terribly useful answer without a better idea of what you intend to use this score for. Is number of discontinuities more important than size? Does it matter whether discontinuities are clumped together or should it make no difference? –  Weeble Feb 16 '12 at 13:59
Ok, I'm using this score to rank a search result. I'm implementing an approximate substring matching using n-grams, and those arrays are the position of n-grams occurences on the searched strings. So a contiguous position should rate better than long non-contiguous one (so contiguity is more important than the length). I'm considering @Weeble's answer. Thanks. –  Muhammad Abrar Feb 16 '12 at 14:05

1 Answer 1

up vote 1 down vote accepted

If you're considering a gap of 2 to be as bad as a gap of 10, then average the "is different by one" function:

differenceMeasures[i] = A[i+1] - A[i] == 1 ? 1 : 0
return average of differenceMeasures
// Note that the average will be sum(differenceMeasures)/(n-1) since there's
// one less difference than there is number of array entries in 'A'.

If you want to take gap sizes into account, I recommend using a monotonically decreasing function bounded at zero like reciprocation:

differenceMeasures[i] = 1 / A[i+1] - A[i]
return average of differenceMeasures
// When the difference is 1, differenceMeasures gets 1.
// When 2, differenceMeasures gets 1/2. Etc...

In both of these functions 1 is the optimal score at 0 is the least optimal. If you don't like that, it's easy enough to return 1 - average of differenceMeasures.

share|improve this answer
I do consider gap sizes. Using reciprocation to "smoothen" the big gaps should be a good idea. –  Muhammad Abrar Feb 16 '12 at 14:43

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