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I'm trying to improve a mostly manual process into mostly automated process, but I'm pretty sure it falls under the category of Knapsack Problems, and I'm having a little trouble coming up with an algorithm I feel confident in.

Here's the setup (I'm rewriting a proprietary problem regarding cloud storage, so excuse the below story for being silly):

I'm selling tickets on my Baseball themed cruise line which invites paying customers to spend a week on the sea with some of their favorite Managers and Players. My goal, then, is to maximize the amount that I can charge per ticket to the customers. The price of a ticket includes a fixed fee (food, drinks, room) + the variable cost based on which Managers and Players are in the Ship.

Each Ship has a very specific configuration of what Managers and Players it can hold (based on permanent decorations that can't be altered). Each Manager and Player has 3 axes that we decorate for: Team, Position, and Country of Origin. For Managers, their Position is typically either the position they're known for playing before Managing (we don't use Managing as a position), or whatever they answered on a self-description survey.

For example, the Glory can hold 2 Yankees Managers, 2 Red Sox Managers, 1 Pitching Manager, and 1 Third Base Manager along with 4 Yankees Players, 4 Red Sox Players, 3 Pitching Players, and 2 Third Base Players. So, 6 total Managers and 13 total Players.

The first wrench in this scenario is that each Manager can only be chosen once, but each Player can actually be chosen unlimited times, so I don't think I can use the Knapsack (0,1) shortcut.

With regard to calculating the ticket cost for a given Ship configuration, we sum the intrinsic value of each Manager and Player (known fixed values) in each Ship. That's easy enough. Next, however, we have to apply all the synergy bonuses. Some are simple, like if a current Pitching Player and his current teammate Catching Player are both in the Ship, it will add a static quantity to the Ship value (which translates linearly to ticket cost). Others are more complicated (the multiplicative ones of the question's title). If a Manager has won a World Series, then for each Player who was part of his World Series winning team that year who is also in the Ship, the Ship value will increase per Player by a fixed amount.

Let's assume the Ted (a Ship), can hold one Braves Manager with 1 Braves Pitcher and 1 Braves First Baseman. We could put current Manager Fredi González in there (who has the highest individual value because he's current) with Players Kimbrel and Freeman. Let's say their individual values sum to 500. If we used 1995 World Series winning Manager Bobby Cox along with Players Glavine and McGriff, their individual values may hypothetically sum to 465. Since Bobby Cox is a World Series winning manager, he adds +20 to total Ship value per Player on the Ship that was also on his team during the win. Therefore, the second configuration is actually a total of 505.

Right now, my approach is to make the best Ship I can, ignoring synergies, and then swap in each World Series winning Manager as I can fit them and see if I can differentially get it to better than general one.

Looking for best approach that isn't "Brute Force"

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Can you post a more formal description of the problem? Something like: "Given a set U of objects, a partitioning of U into classes C of types A and B, maximize the value of containers S where each S has a strict list of classes C to which elements of U must be assigned and... yadda yadda." Any restrictions you have (such as the managerial restriction, or basic restrictions on the pair-wise bonus graph) may help to simplify the problem. –  torquestomp May 17 '13 at 19:42
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