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I have a problem of grouping the students to the nearest examination center. Here are the conditions/constraints:

  1. There are X students and Y examination centers. Each center will hold a different number of students.
  2. The maximum capacity of the total of examination centers can be greater than the number of students, but not smaller.
  3. A student can have the smallest distance to more than 1 examination center.
  4. The examination will hold at the same time for all examination centers.

For example, there are 11500 students and 15 examination centers. 5 centers (1 to 5) will hold 1500 students, 3 for 600 (6 to 8) and the other 7 (9 to 15) will hold 350 students.

I have developed the followings:

  1. A database table with the student's location (register address) to each of the examination centers. Something like below

    Student ID  Dist-Ex1  Dist-Ex2 ... Dist-Ex14  Dist-Ex15
    1            10         70            20         50
    2            25         43            5          105
    11499        35         12             35         55
    11500        5          23              5         5
  2. I can add a column of storing the nearest examination center to each of the student, and create a table like below:

    Ex centers           Nearest for no. of students
    1                     2000
    2                      500
    14                     150
    15                     500

But I don't know how to further proceed. I believe it is some kind of algorithm problem. I would be grateful if anyone would give me some idea.

Thanks a lot in advance!

share|improve this question
This seems to be an instance of the Generalized Assignment Problem, which is NP-hard. Wikipedia has a nice explanation as well as a greedy algorithm that is not guaranteed to be optimal. The agent/task formulation corresponds to your problem if the "agents" are locations and "tasks" are students. The cost is the distance from location to student, and the profit is 1 for each student. – dsg Sep 20 '12 at 6:59
Maybe a max-flow algorithm could fit here – amit Sep 20 '12 at 7:01
up vote 1 down vote accepted

I understood you are looking for an optimal solution - (all students are assigned to their closest examination center). For this, we will reduce the problem to a max-flow problem

Reduce the problem to a bipartite1 graph G=(V,E) such that V = {students} U {examination centers} U {S,T} (all students, all examination centers, and two extra vertices S and T).
E = CLOSESTS U {S} X {examination centers} U {students} X {T} (S is connected to all centers, all students are connected to T, and CLOSESTS - that we will now discuss).
Where CLOSESTS = { (exam,stud) | exam is the closest examination center to the student sutd}

We also need a weight function f:E->N such that:

f(u,v) = capcity if u=S, v=examination center
f(u,v) = 1 if u is examination center and v is student
f(u,v) = 1 if u is student and v is T

The resulting graph should look something like this sample:

enter image description here Now, run a max flow algorithm, like edmonds-karp. If the max flow "enters" T is #num_studets, there is an optimal solution and it is denoted by the flow network achieved by the algorithm2. The max-flow algorithm will find how much flow to put in each edge, which is equivalent to how to assign a student to a center, without breaking the capacity limit.


  • If there is max flow of #students, all edges (student,T) are used, and all student has an incoming flow, and thus is assigned. Also, each examination center has at most capcity students assigned, and the solution is valid.
  • If the max flow is smaller then #students, then there is a student that did not get a flow from an examination center, and is thus not assigned, and there is no optimal solution.

(1) Not exactly a bipartite graph because we added S and T, without it - it was.
(2)According to Integral Flow Theorem, and since all weights are integers - there is an integral solution.

share|improve this answer
thanks a lot for all your help. I will have a look on the max flow as well as genetic algorithms – kwytse Sep 20 '12 at 8:31
@kwytse: You are welcome. Note that genetic algorithm (GA) are heuristic - and do not find optimal solution. If you really want to find the optimal solution, and assign each student to its closest center - max flow is the way to go. Also see the edit - I added a photo that supposed to demonstrate how the graph will look like. – amit Sep 20 '12 at 8:45

I suggest you to take a look on Genetic Algorithms here.

Take population of students and their assignments your fitness function could give the greater value for the students with less overlap.

I've implemented Student/Scheduling problem while being in the university this way, it worked pretty good.

So I believe Genetic Algorithms is a way to go here

Good Luck!

share|improve this answer

(I know this was asked 2 years ago, but maybe it will help someone)

It can be solved optimal with the hungarian algorithm ( creating a bipartite graph as following:

  • The left nodes represent the students
  • The right nodes represent the seats of the 15 centers
  • Insert an edge from each student to each seat with weight = Distance to Center
  • Compute then a minimum weight matching

Problem: Your matrix has size 11500².

Solution: It is possible to model the problem without 'expanding' the centers to their seats using the following algorithm (I will not go into detail):

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