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I want to check if the list values have some level of "closeness". Is there a good algorithm to do this? Bonus points for the most pythonic way.

Valid

[1,7,8,9]
[3,4,100,101,102,103,104,105]

Not Valid

[1,8,9]
[1,10]
[100,200,300,400,500]
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3  
There is a good algorithm. It's called variance –  ControlAltDel May 30 '12 at 18:04
1  
Fairly small, usually 10-20 items. Occasionally around 100. –  spulec May 30 '12 at 18:18
1  
@MariaZverina this is actually not true. For instance, a 6 sided die has even distribution - not normal distribution. But variance can still be applied to sets of repeated rolls –  ControlAltDel May 30 '12 at 18:21
1  
@ControlAltDel Repeated dice rolls have binomial distribution which start to quickly approximated normal distribution. :-) –  Maria Zverina May 30 '12 at 18:23
2  
@ControlAltDel - variance can only be usefully applied to approximately normal distribution. And unless you make tests or determine some other way that distribution is normal, you should not make assumption of normality. :-) –  Maria Zverina May 30 '12 at 18:35

4 Answers 4

up vote 1 down vote accepted

For small lists this O(n^2) algorithm will suffice:

def is_close(l):
    for n in l:
        c = sum([1 for x in l if x >= 0.8 *n and x <= 1.2 * n])
        if c >= 0.7 * len(l):
            return True
    return False

print is_close([1,7,8,9])
print is_close([3,4,100,101,102,103,104,105])
print is_close([1,8,9])
print is_close([1,10])
print is_close([100,200,300,400,500])

Output is:

True
True
False
False
False
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1  
Your tests are probably too strict. Should be >=, <= –  n.m. May 30 '12 at 21:01
    
Good point :) And thanks - it's fixed now. :) –  Maria Zverina May 30 '12 at 21:04
1  
c > 0.7 too ;) –  n.m. May 30 '12 at 21:06
    
Argh :) .. fixed too :) Brain melt ... to hot today :) –  Maria Zverina May 30 '12 at 21:14

Here is a simple linear-time algorithm for an array a that is already sorted (as in the examples, otherwise it needs to be sorted beforehand in O(n log n) time). The idea is to construct and test each maximal subsequence that starts at a given position low.

low = middle = high = 1
while (low <= length (a))
   advance middle to the largest i such that a[i]*0.8<=a[low]
   advance high to the largest i such that a[i]<=a[middle]*1.2
   if ((high-low+1)/length(a)>=0.7) output(true)
   low = low + 1
return (false);

Since low, middle, and high are always increased from 1 through length(a), the running time is always linear in length(a).

If the matching subsequence of a is desired, one can output a[low]...a[high] instead of true.

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Basically a good solution, just a few points: You don't need to go all the way until the lower end reaches the end of the array, it's sufficient that high reaches length(a) or low reaches 0.3 * length(a). Also, I wouldn't just increment low by 1, I'd increment middle by 1, then low until a[low] >= 0.8*a[middle], then again middle to the largest i with a[i]*0.8 <= a[low], then high. Not much difference, but it will do less work if there are big steps in the middle of the array. Anyway, the best solution here, +1. –  Daniel Fischer Jun 2 '12 at 18:10

Here is an algorithm that takes n logn time.

sort the array
for i in range(len(array))
    begin = binary search an index such that array[begin] >= array[i]*0.2
    end = binary search an index such that array[end]*0.2 <= array[i]
    if (end - begin) <= len(array) * 0.7
        70% of the values are within %20 of array[i]
        i.e all elements between begin and end are within 20% of array[i]

Several optimizations, including changing the iteration order, are possible.

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Look up variance: http://en.wikipedia.org/wiki/Variance

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1  
If using numpy, then you can compute the variance with a built in function, numpy.var(array) . –  abought May 30 '12 at 18:12
    
I don't see how that would work. Consider [1, 999997, 999998, 999999, 1000000, 1000001, 1000002, 1000003, 100000000000000000, 100000000000000000000000000000 ]. We have 70% of the values within 20% of some value, but the variance is pretty large. –  Daniel Fischer May 30 '12 at 23:09

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