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I have the following mathematical and proggramming problem: I have a list of about 14000 items. I must chose 4 items so that a + b + c + d - pi = minimal error

going threw all options will take far too long time. I am supposed to build a program (i'm doing it with a python script) that will solve this problem

Any ideas?

Edit: If it helps, the items are ek/10000 - 1 for every k between 0 and about 14400 (that will give pi)

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closed as off-topic by Vote to Close, Niklas B., Sam Mussmann, talonmies, Mark Loeser Mar 9 at 19:48

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Which algorithms have you tried so far? –  mok Mar 9 at 13:25
Are items independent or is there some relation between them? –  bits_international Mar 9 at 13:29
i tried using 4 loops to go over all possible combinations, altough it is not realistic(complexity is o(n^4) and it whould take years to complete) I am open for ideas –  Gadol21 Mar 9 at 13:32
This is a variation of restricted subset-sum. If you can choose a number multiple times - it is easily solveable in O(n^2logn) –  amit Mar 9 at 13:43
This is Project Euler 461 –  Peter de Rivaz Mar 9 at 13:54
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3 Answers 3

up vote 3 down vote accepted

This is a variation of Subset Sum Problem with fixed subset size. (You are facing the optimization problem).
The existence solution (Is there a subset that sums exactly to pi) is discussed thoroughly in the thread: Sum-subset with a fixed subset size.

In your problem (the optimization problem) - if you can repeat an element more than once - it is easily solveable in O(n2log) with O(n2) additional space as follows:

  1. Create an array of size O(n2) containing all possible sum of pairs. Let it be arr.
  2. Sort arr - O(n^2logn)
  3. For each element e of arr - binary search in arr to find the element closest to pi-e.
  4. Yield the two pairs that got the best result in step 3.

The complexity of step 3 is O(logn) per iteration, and n2 iterations - so O(n^2logn) total.

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Would you please prove that this is a variation of the subset sum problem? Or at least give a reference to such a proof? –  mok Mar 9 at 14:20
@mok I think what amit meant is that it is an instance of subset sum –  Niklas B. Mar 9 at 14:38
@NiklasB: There is a tricky difference, the question says that f(a)+f(b)+... - pi should be minimized, so obviously there are some similarities but this small difference may cause a huge difference, and if there isn't such a difference it should be proved. –  mok Mar 9 at 14:41
@mok the optimization problem subset sum asks you to minimize the difference between the sun of a subset and a given value. It's not precisely this but it's close enough. It's definitely Knapsack, but that one is a lot more general –  Niklas B. Mar 9 at 14:46
@NiklasB For sure this is not a proof at all or even near to that (at least I don't prove Sth this way). look [6+75+89+226] is really far from the pi but f200(6) + f200(75) + f200(89) + f200(226) is the closest set to the pi! And I agree with some extent with what you said about the knapsack. We can consider it as a knapsack with capacity of pi. –  mok Mar 9 at 14:51
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You could sort the list of items, which requires O(n log(n) ) time. Then, given a+b+c, you can find the best d using binary search.

You could also (possibly, depending on the data) cut the search tree by checking if the partial sum at any step is too large or too small to have a chance of becoming the correct solution.

By taking these two steps you should be able to reduce the runtime drastically.

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all of this + making sure that the inner loops only run over the later indices like for (int i=0; i<N; ++i) for (int j=i+1; j<N; ++j) ... and some nice break conditions due to the size of the elements (and knowing that they can only increase in size in the next iterations) should easily solve this problem for several thousand input numbers. –  example Mar 9 at 13:59
That will result in a cubic runtime which is too slow for this problem –  Niklas B. Mar 9 at 14:42
It will be O(n^3 log(n) ) which is indeed slower than the subset sum solution (given that element repetition is allowed). –  riklund Mar 9 at 15:01
@riklund You can adapt both algorithms for the cases where repetition is allowed and where repetition is not allowed and get the same runtime :) –  Niklas B. Mar 9 at 19:39
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I suggest you to use Genetic Algorithms with these settings :

Chromosome : [a,b,c,d]

Fitness function: |f10000(a) + f10000(b) + f10000(c) + f10000(d) - π|

Crossover (Ch1,Ch2): Xover([a,b,c,d],[a',b',c',d']) -> [a,b,c',d'] , [a',b',c,d] *

Mutation (Ch) : Mutate([a,b,c,d]) -> [a,b',c,d] **

This problem is really easy for GA to solve and if you implement it you will find it solves the problem in a short time.
* Choose the crossover point randomly

** Replace one of the genes in the chromosome (randomly selected) with one of the possible points

Note that in this post I just gave the key points, however if you are not familiar with the GA at all, you could read about the whole topic and I will help you for more details.

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I love Genetic Algorithms, but I'm not as confident as you are, that this is a good use of them. Your crossover might work, but the mutation will most likely decrease fitness. There are a lot of information we have about the problem that is not represented in your choice of chromosomes, resulting in an artificially bloated search-space ([a,b,c,d] = [b,a,c,d] and other permutations). We can also solve a part of the problem trivially - and it is almost always a good idea with GAs to do so (sort the array and only store three numbers in the chromosomes, find the fourth with a binary search). –  example Mar 9 at 13:55
@example: I agree with you about the quality of this settings but I really don't know how much does he/she know about the GA at all and obviously I should keep the solution as simple as possible until he/she request for more or at least I get a feedback. BTW about representing the domain knowledge inside the genotype I'm agree with you that this is not the best choice (and I said about the reasons) but as you may know the genotype is not the only place to use the domain knowledge, specially you can take advantage of these knowledge in the fitness function. –  mok Mar 9 at 14:09
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