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Suppose we have a set of N real numbers A = {x_1, x_2, ..., x_N}.

The goal is to partition this set into A_1, A_2, ..., A_L subsets with the limitation of sum( A_i ) <= T and minimizing this term:

Cost := sum( abs( sum(A_i) - T ) )

where sum(A_i) denotes the summation of numbers in A_i and T is a given threshold.

I am looking for a non-evolutionary optimal algorithm.

Update: x_i are real positive numbers and not greater than T ( 0 < x_i <= T ).

Update 2: The cost function fixed.

Nice try, Greedy algorithm!

A simple idea is to use a Greedy approach to solve the problem. Here is a pseudocode:

 1. create subset A_1 and set i=1.
 2. remove the largest number x from A.
 3. If sum(A_i) + x <= T
  * put x into A_i
 4. Else
  * create a new subset A_i+1, 
  * put x into A_i+1 
  * set i=i+1
 5. If A is non-empty
  * goto step 2.
 6. Else
  * return all created A_i s

The problem is this solution is not optimal. For example, there are cases that it is better not to put two largest numbers, x1 and x2, in the first subset A_1 even they don't exceed T, because there is no other *x_i* available to add to that set and make its sum closer to T. In the other hand, if we had put x1 and x2 in the separate sets, a better solution could be found (a solution with smaller Cost value).

Possible solutions

I have thought of using a Backtracking algorithm which can find the optimal solution too, but I guess its complexity in this problem would be high.

I have read some article on Wikipedia like Bin packing problem (NP-hard [sighs...]) and Cutting stock problem and apparently my problem is very similar to this standard problems, but I am not sure which one matches my case.

share|improve this question
For what i understood, it looks like you have to solve several knapsack problems, i mean, solve a knapsack for T, so you get a set A_1 that has min cost, but close enought to T, and then you run a knapsack again (removing the A_0 elements from A) so you get a new A_1 optimal and close to T, then you repeat again until you find all the A_i – higuaro Jun 2 '12 at 0:17
@h3nr1x: I guess this is what greedy solution does. While this approach finds optimal solutions for each knapsack, it fails to find a global optimum solution (An example is given in the question). – Isaac Jun 2 '12 at 1:06
There is something wrong with the term to minimize because it is constant regardless of how the sets are partitioned. It is always equivalent to the sum of all N numbers minus T times L. – Antti Huima Jun 2 '12 at 6:02
@antti.huima: Good point. I guess this term is just minimzing the number of subests. For example, it prevents the solution where only one x_i is placed in every set. Anyway, I am not sure if this is the only role of minimizing term. – Isaac Jun 2 '12 at 10:40
@Isaac you can't but x_i in every set if you are looking for a "partition" as you write. Partition implies that the sets are disjoint. If you can have the same element in multiple sets it is not a partition but just a set of subsets. – Antti Huima Jun 2 '12 at 14:09
up vote 2 down vote accepted

Update: With the corrected cost function, note that sum(A_i) - T will always be negative as A_i <= T. So our objective is to minimize

sum(abs(sum(A_i)-T)) = sum(T-sum(A_i)) = L*T-sum(A)

sum(A) is constant, so the task is to minimize the number of used bins. Therefore your problem is equivalent to classic bin packing.

For solving this you could use a bin packing solver like this one.

share|improve this answer
Thanks. Apparently I made a mistake in the definition of cost function and omitted a abs. The question is now updated. – Isaac Jun 2 '12 at 16:12
Thanks for updating the answer and providing a proving. – Isaac Jun 3 '12 at 8:45

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