# how to solve integer linear programming when one of the variables belong to a set

I am working on solving optimization problems using integer linear programming, one of the constraints assume that the variable has a value belongs to a set of values like the following

`````` min 5*x1 + 2*x2
s.t.
x1,x2>0
x1 in {2,4,-5}
``````

how i can represent this problem to solve it using CPLEX or lp_solve in matlab? what are the values of F,A,b arrays?

Thanks

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One thing you can try is writing `x1 = 2 * b1 + 4 * b2 -5 * b3` s.t. `0 <= b1, b2, b3 <= 1` and `b1, b2, b3 integer`. –  Ben Voigt Apr 10 at 19:23
@BenVoigt : That would work, but you would need to put an additional constraint of `(b1 + b2 + b3) <= 1`, otherwise `x1 = 6` may be a solution with `b1=1, b2=1, b3=0` –  dhrumeel Apr 10 at 19:31
@dhrumeel: Sorry, yes. I intended that `b1 + b2 + b3 = 1` and then forgot to type that into my question. (It needs to be equality, since `x1 = 0` is not allowed) –  Ben Voigt Apr 10 at 19:36
x1 = 0 is already avoided by the bounds `x1,x2>0` in the original problem. I guess that makes the (-5) term redundant as well. Also, many ILP solvers do not take equality constraints, so if we do want equality we would need to say `b1 + b2 + b3 <= 1` and `b1 + b2 + b3 >= 1` –  dhrumeel Apr 10 at 19:39
@dhrumeel: Yes, I included that well-known method of converting equality constraints, as well as a trick for making it compatible with interior-point methods. Whether strict inequality constraints are allowed depends on the solution method (e.g. barrier method solvers make all inequalities strict). Of course, one could instead use `-x1 <= -1` and still have `{2, 4}` feasible –  Ben Voigt Apr 10 at 19:43

You can rewrite a problem where an integer variable takes on a finite discontiguous set of possible integral values as a binary program in more variables. Just write:

``````2 * b1 + 4 * b2 -5 * b3 - x1 = 0
b1 + b2 + b3 = 1
``````

with `b1, b2, b3` constrained as binary. That might be directly supported, or else expressed as

``````b1, b2, b3 integer
0 <= b1, b2, b3 <= 1
``````

In case you aren't allowed equality constraints, remember that a pair of inequality constraints is equivalent.

`````` Ax = b;
``````

is the same as

`````` Ax <= b
-Ax <- -b
``````

But the solution set still has no interior, so interior point methods can't work. You can relax that by:

`````` Ax - e <= b
-Ax - e <= -b
``````

and minimize `e` using your objective function.

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