Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have job that needs to be done in 14 days. I have 5 workers. One day need exactly 3 workers. Each worker can only work maximum 9 days. Each worker has their day preference, each day for each worker has different cost.

Now, how do I solve this in mathematics term? How do I find the lowest cost possible for the worker assignment?

I don't think this is assignment problem since the Hungarian algorithm is designed so that I can only find 1-to-1 assignment. (In this case, 1 worker for 1 day)

share|improve this question

3 Answers 3

It can be a bin-packing and tsp problem. Look for capacited vehicle routing problem. It shares many problems but you have exactly 3 workers. In capacited vehicle routing there is x workers. It think you need more information.

share|improve this answer

What you need to solve this problem is an IP (Integer Programming) formulation. Your intuition is right, this is very similar to an assignment problem -- we are essentially assigning workers to work on certain days.

Here are the steps to formulate the problem:

Decision variable: (In English) Which worker works on which days?

Let's label the days t (1..14) And the workers w1 to w5.

So,

X_wt = 1 if worker w works on day t

X_wt = 0 otherwise

The constraints are now fairly straight forward to write down. Each day needs exactly 3 workers.

X_1t + X_2t + X_3t + X_4t + X_5t = 3 for each t (1..14)

Each worker can work for a maximum of 9 days:

(sum over t=1..14) X_wt <= 9 for each w (1..5)

And finally, the Objective function:

Let C_wt be the cost of hiring worker w on day t. With a double summation:

Min (sum over w 1..5)(sum over t 1..14) C_wt

And in order to accommodate worker preferences for days, you can layer on yet another set of costs, say P_wt.

That's the basic formulation. You will then need an IP/LP solver (such as CPLEX or Excel Solver or R's optim library) to get the actual solution.

Hope that helps.

share|improve this answer

This can be solved as a minimum-cost network-flow problem on a bipartite graph. Each worker represents a source with a supply of 9 units, and each day represents a sink with demand of 3. The arcs between the supply and demand each have capacity 1, and a cost corresponding to their preference to be off on that day. If there is flow along an arc, that means that a particular worker should be working that day.

Although this can't be solved with a Hungarian method, but with several fast algorithms, including network simplex.

Algebraically, the formulation is

minimize sum_w sum_d p_wd x_wd
subject to
\sum_w x_wd = 3    forall d
\sum_d x_wd <= 5   forall w

if p_wd is worker w's preference for day d. This is a totally unimodular constraint matrix, so it does not require a mixed-integer solver.

share|improve this answer
    
Hmm. This seems close. But how do you decide which 3 to assign out of the 5 available workers? Sorry, I'm still new in Operation Research, never learned all these during university years. Now I'm self-learning. –  user1491884 Oct 28 '12 at 18:55
    
@user1491884 The network-simplex algorithm will give you a flow satisfying the demand at each sink node and not exceeding the capacity at each source node at a minimum cost. –  David Nehme Oct 29 '12 at 2:25

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.