I'm trying to frame If-Then-Else-If... conditions in Python's PuLP.

I've looked at If-Then and If-Then-Else in MIP. However, I'm trying to understand how to propagate the choices further down to the next set of constraints and how to handle more than 2 decision branches.

To explain, consider the conditional constraints shown in the image shown here:

x and y are my decision variables. Basically, this reads as:

if x=0: C2>0 
elif x=1: C10>0
elif x=2: C3>0

if x=0 and y=0: 
elif x=0 and y=1: 
elif x=2 and y=0: 
elif x=2 and y=1: 

I know how to use the "Big M" technique for simple if-then-else situations. So for instance, if the problem was:

   if (x = 1) then (A < 0) else (B < 0)
   problem += A < M1*(1-x)
   problem += B < M2*x

What I don't understand is, how to change this for:

  1. If there's more than 2 branches, so it's no longer a multiplication with x and (1-x).
  2. If there are subsequent branches below the original decision, with more decisions that all depend on values from above.

There are really three steps involved here:


Reformulate the x variables so they are binary instead of in {0,1,2}. (Strictly speaking, this isn't necessary, but I think it makes the solution cleaner and easier to generalize.)

So, introduce three new binary variables x0, x1, x2 and constrain them as follows:

x0 >= 1 - x
x0 <= 1 - 0.5x

x2 >= x - 1
x2 <= 0.5 x

x1 = x - 2x2

So: If x = 0, then the first two constraints require x0 = 1, the second two require x2 = 0 and the last requires x1 = 0. And similarly if x = 1 or x = 2. (You should double-check my logic.)

Your model will include your original x variables plus the new binary variables.


Create a new binary decision variable called, say w_ijkl, which equals 1 if x0 = i, x1 = j, x2 = k, and y = l, for i, j, k, l in {0,1}. Enforce this definition through the following constraints:

w_ijkl >= i*x0 + (1-i)*(1-x0) + j*x1 + (1-j)*(1-x1) +
          k*x2 + (1-k)*(1-x2) + l*y + (1-l)*(1-y) - 3
w_ijkl <= 0.25 * [i*x0 + (1-i)*(1-x0) + j*x1 + (1-j)*(1-x1) +
                  k*x2 + (1-k)*(1-x2) + l*y + (1-l)*(1-y)]

The first constraint says that if all four variables equal their targets (i, j, etc.) then w_ijkl must equal 1, and otherwise it can equal 0. The second constraint says that if all four equal their targets, then w_ijkl may equal 1, otherwise it must equal 0.

So, for example, w_0110 gets these constraints:

w_0110 >= 1-x0 + x1 + x2 + (1-y) - 3
w_0110 <= 0.25 * [1-x0 + x1 + x2 + (1-y)]


Use big-Ms as desired to turn constraints on and off. So, for example, to require C6 >= 0 if x=2 and y=0, use:

C6 >= M * (w_0010 - 1)

(By the way, in general you can't use strict inequality constraints in a MIP -- you need greater-than-or-equal or less-than-or-equal constraints.)

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.