If you are minimizing an increasing function of `|x|`

(or maximizing a decreasing function, of course),
you can always have the aboslute value of any quantity `x`

in a lp as a variable `absx`

such as:

```
absx >= x
absx >= -x
```

It works because the value `absx`

will 'tend' to its lower bound, so it will either reach `x`

or `-x`

.

On the other hand, if you are minimizing a decreasing function of `|x|`

, your problem is not convex and cannot be modelled as a `lp`

.

For all those kind of questions, it would be much better to add a simplified version of your problem *with the objective*, as this it often usefull for all those modelling techniques.

**Edit**

What I meant is that there is *no* general solution to this kind of problem: you cannot in general represent an absolute value in a linear problem, although in practical cases it is often possible.

For example, consider the problem:

```
max y
y <= | x |
-1 <= x <= 2
0 <= y
```

it is bounded and has an obvious solution (2, 2), but it *cannot* be modelled as a lp because the domain is not convex (it looks like the shape under a 'M' if you draw it).

Without your model, it is not possible to answer the question I'm afraid.

**Edit 2**

I am sorry, I did not read the question correctly. If you can use binary variables *and* if all your distances are bounded by some constant `M`

, you can do something.

We use:

- a continuous variable
`ax`

to represent the absolute value of the quantity `x`

- a binary variable
`sx`

to represent the sign of `x`

(`sx = 1`

if `x >= 0`

)

Those constraints are always verified if `x < 0`

, and enforce `ax = x`

otherwise:

```
ax <= x + M * (1 - sx)
ax >= x - M * (1 - sx)
```

Those constraints are always verified if `x >= 0`

, and enforce `ax = -x`

otherwise:

```
ax <= -x + M * sx
ax >= -x - M * sx
```

This is a variation of the "big M" method that is often used to linearize quadratic terms. Of course you need to have an upper bound of all the possible values of `x`

(which, in your case, will be the value of your distance: this will typically be the case if your points are in some bounded area)