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.

Lets have two points, (x1, y1) and (x2,y2)

dx = |x1 - x2|

dy = |y1 - y2|

D_manhattan = dx + dy where dx,dy >= 0

I am a bit stuck with how to get x1 - x2 positive for |x1 - x2|, presumably I introduce a binary variable representing the polarity, but I am not allowed multiplying a polarity switch to x1 - x2 as they are all unknown variables and that would result in a quadratic.

share|improve this question

1 Answer 1

up vote 1 down vote accepted

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)

share|improve this answer
    
Actually the distance is just constrained and the cost function is on variables indirectly related. Thus whether its a min or a max is not really known. –  Tom Larkworthy Oct 5 '13 at 23:00
    
In that case, you need to post your problem (or at least a simplified version) if it is possible: see my edit above. –  Nicolas Grebille Oct 6 '13 at 5:12
    
Sorry about the mess! It is actually possible with binary variables if the distances are bounded, see the second edit ;) –  Nicolas Grebille Oct 6 '13 at 5:32
    
Oh yeah that works. If x = -1 then sx is 0. Then we have: The top pair of constraints becomes ax <= -1 + M, and ax>= -1 - M. Which is true The bottom pair of constraints become ax <= 1 and ax >= 1 which is true and constricts ax to 1 –  Tom Larkworthy Oct 7 '13 at 17:05

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.