I am working on a program in Python in which a small part involves optimizing a system of equations / inequalities. Ideally, I would have wanted to do as can be done in Modelica, write out the equations and let the solver take care of it.
The operation of solvers and linear programming is a bit out of my comfort zone, but I decided to try anyway. The problem is that the general design of the program is object-oriented, and there are many different possibilities of combinations to form up the equations, as well as some non-linearities, so I have not been able to translate this into a linear programming problem (but I might be wrong) .
After some research I found that the Z3 solver seemed to do what I wanted. I came up with this (this looks like a typical case of what I would like to optimize):
from z3 import * a = Real('a') b = Real('b') c = Real('c') d = Real('d') e = Real('e') g = Real('g') f = Real('f') cost = Real('cost') opt = Optimize() opt.add(a + b - 350 == 0) opt.add(a - g == 0) opt.add(c - 400 == 0) opt.add(b - d * 0.45 == 0) opt.add(c - f - e - d == 0) opt.add(d <= 250) opt.add(e <= 250) opt.add(cost == If(f > 0, f * 50, f * 0.4) + e * 40 + d * 20 + If(g > 0, g * 50, g * 0.54)) h = opt.minimize(cost) opt.check() opt.lower(h) opt.model()
Now this works, and gives me the result I want, despite it not being extremely fast (I need to solve such systems several thousands of times). But I am not sure I am using the right tool for the job (Z3 is a "theorem prover").
The API is basically exactly what I need, but I would be curious if other packages allow a similar syntax. Or should I try to formulate the problem in a different way to allow a standard LP approach? (although I have no idea how)