**Problem**

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.

x_iis 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