Ok this is an abstract algorithmic challenge and it will remain abstract since it is a top secret where I am going to use it.

Suppose we have a set of objects O = {o_1, ..., o_N} and a symmetric similarity matrix S where s_ij is the pairwise correlation of objects o_i and o_j.

Assume also that we have an one-dimensional space with discrete positions where objects may be put (like having N boxes in a row or chairs for people).

Having a certain placement, we may measure the cost of moving from the position of one object to that of another object as the number of boxes we need to pass by until we reach our target multiplied with their pairwise object similarity. Moving from a position to the box right after or before that position has zero cost.

**Imagine an example** where for three objects we have the following similarity matrix:

```
1.0 0.5 0.8
S = 0.5 1.0 0.1
0.8 0.1 1.0
```

Then, the best ordering of objects in the tree boxes is obviously:

```
[o_3] [o_1] [o_2]
```

The cost of this ordering is the sum of costs (counting boxes) for moving from one object to all others. So here we have cost only for the distance between o_2 and o_3 equal to 1box * 0.1sim = 0.1, the same as:

```
[o_3] [o_1] [o_2]
```

On the other hand:

```
[o_1] [o_2] [o_3]
```

would have cost = cost(o_1-->o_3) = 1box * 0.8sim = 0.8.

**The target** is to determine a placement of the N objects in the available positions in a way that we minimize the above mentioned overall cost for all possible pairs of objects!

**An analogue** is to imagine that we have a table and chairs side by side in one row only (like the boxes) and you need to put N people to sit on the chairs. Now those ppl have some relations that is -lets say- how probable is one of them to want to speak to another. This is to stand up pass by a number of chairs and speak to the guy there. When the people sit on two successive chairs then they don't need to move in order to talk to each other.

So how can we put those ppl down so that every distance-cost between two ppl are minimized. This means that during the night the overall number of distances walked by the guests are close to minimum.

Greedy search is... ok forget it! I am interested in hearing if there is a standard formulation of such problem for which I could find some literature, and also different searching approaches (e.g. dynamic programming, tabu search, simulated annealing etc from combinatorial optimization field).

Looking forward to hear your ideas.

PS. My question has something in common with this thread Algorithm for ordering a list of Objects, but I think here it is better posed as problem and probably slightly different.