I am trying to solve a linear optimization problem using Pulp in Python.

Here is the code:

```
import pandas as pd
import pulp
D_XB = 20
D_XP = 0
D_XC = 0
Available_Time = 1440 #in minutes
test = [['A1', 'A2', 'A3', 'A4', 'A5'], [1,2,1,0,3], [16,32,0,16,32], [10,10,10,10,10], [120,210,180,180,350]]
Cycles = pd.DataFrame(test, index=['Cycles', 'QTA1', 'QTA2', 'QTA3', 'T_TOT']).T
A1 = pulp.LpVariable("Cycle_A1", lowBound=0, cat='Integer')
A2 = pulp.LpVariable("Cycle_A2", lowBound=0, cat='Integer')
A3 = pulp.LpVariable("Cycle_A3", lowBound=0, cat='Integer')
A4 = pulp.LpVariable("Cycle_A4", lowBound=0, cat='Integer')
A5 = pulp.LpVariable("Cycle_A5", lowBound=0, cat='Integer')
# Defining the problem as a minimization problem (Minimize Storage)
problem_5 = pulp.LpProblem("Storage_Minimization_3", pulp.LpMinimize)
S_XB = pulp.lpSum((Cycles.iloc[0]["QTA1"])*A1 + (Cycles.iloc[1]["QTA1"])*A2 + (Cycles.iloc[2]["QTA1"])*A3 + (Cycles.iloc[3]["QTA1"])*A4 + (Cycles.iloc[4]["QTA1"])*A5)
S_XP = pulp.lpSum((Cycles.iloc[0]["QTA2"])*A1 + (Cycles.iloc[1]["QTA2"])*A2 + (Cycles.iloc[2]["QTA2"])*A3 + (Cycles.iloc[3]["QTA2"])*A4 + (Cycles.iloc[4]["QTA2"])*A5)
S_XC = pulp.lpSum((Cycles.iloc[0]["QTA3"])*A1 + (Cycles.iloc[1]["QTA3"])*A2 + (Cycles.iloc[2]["QTA3"])*A3 + (Cycles.iloc[3]["QTA3"])*A4 + (Cycles.iloc[4]["QTA3"])*A5)
Tot_Time = pulp.lpSum((Cycles.iloc[0]["T_TOT"])*A1 + (Cycles.iloc[1]["T_TOT"])*A2 + (Cycles.iloc[2]["T_TOT"])*A3 + (Cycles.iloc[3]["T_TOT"])*A4 + (Cycles.iloc[4]["T_TOT"])*A5)
Stock_XB = (S_XB - D_XB)
Stock_XP = (S_XP - D_XP)
Stock_XC = (S_XC - D_XC)
problem_5 += Stock_XB + Stock_XP + Stock_XC
# Constraints: Time constraint present
problem_5 += S_XB >= D_XB
problem_5 += S_XP >= D_XP
problem_5 += S_XC >= D_XC
problem_5 += A1 >= 0
problem_5 += A2 >= 0
problem_5 += A3 >= 0
problem_5 += A4 >= 0
problem_5 += A5 >= 0
problem_5 += Tot_Time <= Available_Time
# Solving the probelm
status = problem_5.solve()
result = pd.DataFrame({'A1':[pulp.value(A1)], 'A2':[pulp.value(A2)], 'A3':[pulp.value(A3)], 'A4':[pulp.value(A4)], 'A5':[pulp.value(A5)],
'Demand XB':[D_XB], 'Demand XP':[D_XP], 'Demand XC':[D_XC], 'Minimum storage':[pulp.value(problem_5.objective)],
'Stock_XB':[pulp.value(Stock_XB)], 'Stock_XP':[pulp.value(Stock_XP)], 'Stock_XC':[pulp.value(Stock_XC)],
'Total Time needed':[pulp.value(Tot_Time)]})
```

Terminology: S_* is the production of a certain item, D_* is the demand of that item. These are defined before the definition of the probelm.

This problem is not always feasible because sometimes production exceeds the time available. In this case I would like the constraints on the cycles to be respected and the one on time should be broken in order to solve the problem.

How can I achieve this?

Thanks, Carlotta.

`S_*`

and`D_*`

parameters or pulp variables? If they are parameters, this is not really a constraint given that it does not involve any pulp variable. If they are pulp expressions, you're missing their definitions. The easiest is for you to give a complete example with all the needed data.`S_*`

and`D_*`

. Basically`D_*`

is the demand that I get from the dataset the client provided. The supply is then calculated using the result of the problem. The goal is to find which cycles let me produce the items needed storing as less as possible.