Let's say I have matrix D
D <- data.frame(rbind(c(1,1,1), c(1,1,0),c(1,1,0),c(1,1,0),c(1,0,0), c(0,0,0),c(1,0,0),c(1,0,0),c(1,1,0), c(1,0,0),c(1,1,1),c(1,1,0),c(1,0,0), c(1,0,0),c(1,0,1)))
I am searching for the one-to-one matching that minimizes overall cost (the assignment problem). Doing this with the R package lpSolve is straightforward.
costs <- as.matrix(dist(t(D), method="manhattan")) library(lpSolve) solution <- lp.assign(costs)$solution apply(solution > 0.999, 2, which)
This returns the "best" candidate but I also want the second and third best. In fact, what I'd like to do is to use a much larger D matrix , let's say:
and get the best 200 candidates (ranked from 1st best to 200th). Is there a quick way to do this in R? Someone suggested that I should:
- optimize and find the best candidate (same as above)
- then add a constraint eliminating just the optimal solution and re-solve to optimality
Repeating this 200 times should get me the best 200 candidates. The last optimization will have 199 constraints (the 199 "better" candidates).
Unfortunately the lp.assign function (package lpSolve) which is built for solving the assignment problem doesn't include a constraint field. If you open the function (fix(lp.assign)) you'll find the lp code with constraints such as const.count, but I don't really understand how I'd impose the solution constraints.At this point I'm also not sure that lp.assign is the right algorithm for what I need.