# Modelling combinatorial optimization? problem

I've been unable to match this problem into some canonical one, and I would like some guides to build/use an algorithm and solve it. Description is as follows:

We have some people who want breakfast. Each one may order any number of coffee, juice and toast. We accumulate the order for all the group.

`InitialOrder = { C1, J1, T1 } with C1, J1, T1 being integer non-negative numbers.`

Each component has a given price, so the total price of the initial order is

`InitialPrice = C1 * Pc + J1 * Pj + T1 * Pt with Pc, Pj, Pt being rational positive numbers`

Cafeteria has also 'breakfast menus' consisting in combinations of standard items

```full breakfast = coffee + juice + toast
normal breakfast = coffee + toast
```

Choosing these menus is cheaper than choosing each component separately, so we have

```Pf < Pc + Pj + Pt
Pn < Pc + Pt
Pb < 2 * Pt
with Pf, Pn, Pb being rational positive numbers
```

People want to group the initial order into menus to minimize the total amount spent. Then

`FinalOrder = { C2, J2, T2, F, N, B } with C2, J2, T2, F, N, B integer non-negative numbers`

and we'll have a FinalPrice <= InitialPrice as

`FinalPrice = C2 * Pc + J2 * Pj + T2 * Pt + F * Pf + N * Pn + B * Pb with Pc, Pj, Pt, Pf, Pn, Pb as rational positive numbers`

All prices (Pc, Pj, Pt, Pf, Pn and Pb) are known in advance.

Please, do you know Which approach should I follow to build an algorithm to minimize FinalPrice for a given InitialOrder? Feel free to ask any more details you need.

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This looks like a Linear Integer Programming problem.

You have six variables and a linear equation (for final price) which you need to minimize, given linear constraints (must match initial order). The restriction being that the variables are non-negative and take integer values.

For instance in your example case it will be (I am presuming your actual problem is more complicated than your example :-))

Minimize

``````C2 * Pc + J2 * Pj + T2 * Pt + F * Pf + N * Pn + B * Pb
``````

(Multiply Pc etc with a suitable integer to make them integers if needed)

Subject to the constraints that

``````   C2 + F + N = C1
T2 + F + N + 2B = T1
J2 + F = J1
``````

In the general case, Integer Programming is NP-Hard, but given the small size of the problem and the constraints, standard solving techniques can probably quickly solve it for you.

Hope that helps.

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Excuse me if I'm wrong but I think the six final variables are not independent (menus are composed from items). Is it possible to model this restriction into LIP? –  fglez Aug 10 '10 at 18:30
@antispam: Yes those are the constraints I was talking about. I will have edited the answer to make it clearer. –  Aryabhatta Aug 10 '10 at 18:34
I will try to follow this direction and update the question with my findings. Thank you! –  fglez Aug 10 '10 at 18:43
After some successful tests, I'll be using simplex to solve linear relaxation and then branch and bound to find integer solution as there are not too many variables. –  fglez Aug 11 '10 at 18:10
@anti: Glad your tests were successful. Hope you are using one of the many solvers already written :-) –  Aryabhatta Aug 11 '10 at 18:16

If you don't want to go the whole hog (integer linear programming, which is a reasonably complex area), consider an exhaustive tree search using branch-and-bound. BnB is essentially depth-first search where you backtrack at any point where the cost of the current branch is greater than or equal to the best solution you have found so far.

As Moron says, though, for any large problem you're going to need ILP.

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At the end I'll be using B&B after simplex to search for integer solutions. Thanks for your response. –  fglez Aug 11 '10 at 18:13
You should probably try B&B on vanilla depth first search and see if that finds results quickly enough. Moving from an LP solution into an integer solution is something of a black art and is a huge research area. If you're looking for an high quality free ILP solver, take a look at SCIP (scip.zib.de). –  Rafe Aug 11 '10 at 22:44

Since your problem is closely related to bin packing (or at least the vector version of it), some of the associated heuristics might also come in handy. Specifically, a greedy heuristic where you greedily pack full breakfasts (or 2*normal + toast depending on the relative costs) first, and then continue in this vein, might suffice.

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Depending on prices, it may not have optimal substructure so there would be a chance for a suboptimal solution. Thank you for the suggestion anyway. –  fglez Aug 11 '10 at 18:22