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I have the following constraint inequalities and equalities:

$$Ax \leq b$$ $$A_{eq}x = b_{eq}$$

The problem is that the objective function, which I am asked to minimized, is defined as

$$f=\sum\limits_{i=1}^{m}u([\sum\limits_{j=1}^{n}k_{ij}x_j]-c_{i})$$

where $u(x)$ is the Heaviside step function.

Strictly speaking, this is not a linear programming problem ( although quite close!), so it can't be attacked by the standard linear programming techniques.

I'm aware that I can approximate the step function into a smooth function, but this is not the route I plan to take now.

What are the techniques that are available for this kind of problem?

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    one choice is to replace the step function with a smooth approximation, and then to use some nonlinear solver.2011-01-08
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    @Slowsolver, is there another choice?2011-01-09
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    The objective should be to minimize $\sum_i u(t_i)$, not $\sum_i t_i$, right? I like Fanfan's approach though I'm not sure if it'll work in this case since if $\sum_j k_{ij} x_j - c_i \leq 0$, then $t_i$ is not necessarily 0 though it needs to be.2012-05-23
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    Strike that. It would still work because of the minimization objective. If the objective were to maximize, then it would not.2012-05-23

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Your problem can be converted in a mixed-integer program in the following way: for each term in the objective function of the form $$u\Bigl(\sum_j k_{ij} x_j - c_i\Bigr) ,$$ introduce an auxiliary binary variable $t_i \in \{0,1\}$ and add the constraint $$\sum_j k_{ij} x_j - c_i \le M t_i$$ where $M$ is a sufficiently large constant (it has to be larger than all possible values for the argument of $u$). You can then replace the objective function by the sum of the binary variables, i.e. minimize $\sum_i t_i$ and check that the constraint ensures that the problem is equivalent to the original one (note that this assumes the convention $u(0)=0$).

Mixed-integer programs are harder to solve than linear programs, but you are guaranteed to find a globally optimal solution exactly.