# Diving n numbers into k segments with following properties

given n numbers a[0],a[1],.....,a[n-1]. we have to divide it into k segments such that..

Any Segment should have at-least 1 element The segment should contain numbers in given sequence Eg: we can divide 20 numbers into 3 segments such that {a[0],a[1],....,a[6]},{a[7],a[8],.....a[15]},{a[16],a[17],....a[19]}

sum_segment[i] is defined as sum of all numbers in the segment i.

The segments should be in such a way that the standard deviation of sum_segment of all the segments should me maximum.

How can we do that?

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Did you seriously just cut-and-paste your homework assignment? How do you expect to learn? –  Eric J. May 3 '12 at 16:50
Its not my assignment. I was working on a project and i came across this problem. I am thinking that what is the best time complexity in doing this problem? I just wanted a better solution and want to compare it with the genetic algorithm. –  Raghu May 4 '12 at 9:41
How can we do it if the question is as follows: si is the standard deviation of the segment, sum of the standard deviations of all segments should be maximum? –  Raghu May 4 '12 at 10:44

This problem is a dynamic programming problem.

I want to solve this for you, but I feel like this may be a homework problem.

I will instead point you in the right direction.

Biggest Hint: Approach this problem the same way you approach the Segmented Least Squares Problem.

More on that here on slide 15.

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Thanks! What do you think is GA or DP better to solve this? In case we have 1000 numbers and number of segments can be ins 100s –  Raghu May 4 '12 at 11:59
Use DP. GA don't give you exact results. If you code well, datapoints can be large. GA takes time too because it isn't precise about finding the right solution. –  Kaushik Shankar May 4 '12 at 12:01

Let us talk a bit about standard deviation. Let s1,s2,...,sk be the sum of each segment in a given partition.

First, maximizing variance is equivalent to maximizing standard deviation. So let us use variance.

Variance = ( \sum(si^2) - (\sum si)^2 )/k

Since we are optimizing for a given 'k' we can drop k from this equation. Also, for any partition \sum si is the same (it is sum of all the elements), so let us drop that too.

Essentially we need to find a partition such that \sum(si^2) is maximized. Which you can do with dynamic programming. Let me know if you don't know how.

HINT

Assume you have i numbers and k=2. You can iterate through i and partition it in such a way that s1^2+s2^2 is maximum. Do it for all i<=n. For k =3, for a given i, first partition it into two parts and use the sums calculated in first step to find two sub-partitions that maximize sum using k=2, and just use s3^2 for second part. And so on.

F(i,k) = max_j=1..i( F(j,k-1) + ( \sum_l=(j+1)..n x[l] )^2 )

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Can you tell me how to do it using dynamic programming? What do you think the complexity will be? –  Raghu May 4 '12 at 9:32
How can we do it if the question is as follows: si is the standard deviation of the segment, sum of the standard deviations of all segments should be maximum? –  Raghu May 4 '12 at 10:42
@Raghu See the hint –  ElKamina May 4 '12 at 15:34