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Have 180 balls.

Have 70 buckets.

Each ball's value depend on which bucket it's in:

ball1 = { 1, 14, 2, 3, 4 ... } //70 values in total for each bucket
ball2 = { 24, 2, 23, 2, 5 ... }

Each bucket has a max number balls it can carry, but total number of balls the 70 buckets can carry is 180, i.e. all 180 balls will fit exactly. (every bucket has to carry at least 1 ball)

{bucket1, 3} {bucket2, 1} { bucket3, 2} {bucket4, 1} ...

How do you maximize the ball placement on this?

I tried to bruteforce, and quickly regretted it after counting the number of permutations.

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well, obviously it can't be brute forced because of O(n!) complexity in that case. this sounds like dynamic programming to me. –  darxsys Jun 6 '13 at 7:15
Hmm it's similar to the knapsack problem but with 70 knapsacks and changing values that depend on which knapsack. I'm not sure how to extend it though. –  bunnybare Jun 6 '13 at 7:24
What do you mean? A ball is just a ball. Although each ball's value changes depending on which bucket it's placed. –  bunnybare Jun 6 '13 at 7:57
@bunnybare I deleted my comment after realising what it meant. I had just woke up and my mind couldn't conceive balls changing "values" depending on which bucket they were placed, so I thought it must have had another meaning (I'm not a native English speaker). –  fortran Jun 6 '13 at 8:05
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2 Answers

up vote 5 down vote accepted

It seems like a bipartite graph maximum weight matching problem. The tricky part is how to construct the bipartite graph so that we can apply a polynomial time algorithm to solve the problem.

To make the problem easier, say we have 3 balls, and 2 buckets:

Ball 1: {1, 10},
Ball 2: {9, 20},
Ball 3: {7, 9};

Bucket 1: 2
Bucket 2: 1

and I would like to construct the graph like the following:

enter image description here

The main idea is to construct a bi-graph such that the left part of nodes stand for the Balls, while the other part are the buckets' nodes. And we give as many nodes as the capacity of each bucket, and now we can apply a maximum weight matching algorithm to solve our problem.

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To construct the graph, wouldn't it be enough to have a collection of all the edges? m*m edges? Gonna go look up how to do max weight matching algo. –  bunnybare Jun 6 '13 at 8:05
@bunnybare, yes, if we have m balls, there will be m*m edges. This wiki will be helpful: en.wikipedia.org/wiki/KM_algorithm –  Marcus Jun 6 '13 at 8:16
Thanks for the link, I'm reading it now. –  bunnybare Jun 6 '13 at 8:42
@bunnybare, you're welcome. –  Marcus Jun 6 '13 at 8:45
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Because of the complexity, this is a type of problem that is best solved by an "what optimal result can I achieve in a fixed amount of time" approach. If you need the true global maximum than this will not work for you.

My first approach would be along the lines of simulated annealing:

1) Place the balls at random (subject to your at least one ball in each bucket constraint)

2) Compute the objective function (you must already have this from your brute force approach)

3) Consider operations like swapping two balls at random, moving one ball into another bucket (if the constraint allows).

4) Recompute the objective function

5) Always accept the change if the objective function is better, but also (and this is important), accept the change too if the objective function is worse with a probability that decays exp(-constant * time). (That's called the temperature function).

6) Go round again.

This approach will allow good buckets to stick together and, in early stages, allow the state to bounce away from a local maximum. The science here is to figure out a good value for 'constant'.

See http://en.wikipedia.org/wiki/Simulated_annealing

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Hmm. I have started exploring this option; trying to see how to implement the probability function properly. When do you suggest resetting? –  bunnybare Jun 6 '13 at 7:42
"When do you suggest resetting?": sorry I don't understand. –  Bathsheba Jun 6 '13 at 7:43
Nevermind, I read that it's just a matter of preference. I meant when to stop the current climb and rearrange the balls and climb again, to avoid getting stuck on a local maxima. –  bunnybare Jun 6 '13 at 7:46
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