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Im using PuLP to solve some minimization problems with constraints, uper and low bounds. It is very easy and clean.

But im needing to use only the Scipy and Numpy modules.

I was reading: http://docs.scipy.org/doc/scipy/reference/tutorial/optimize.html

Constrained minimization of multivariate scalar functions

But im a bit lost... some good soul can post a small example like this PuLP one in Scipy?

Thanks in advance. MM

from pulp import *

'''
Minimize        1.800A + 0.433B + 0.180C
Constraint      1A + 1B + 1C = 100
Constraint      0.480A + 0.080B + 0.020C >= 24
Constraint      0.744A + 0.800B + 0.142C >= 76
Constraint                            1C <= 2
'''

...
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1 Answer 1

up vote 2 down vote accepted

Consider the following:

import numpy as np
import scipy.optimize as opt

#Some variables
cost = np.array([1.800, 0.433, 0.180])
p = np.array([0.480, 0.080, 0.020])
e = np.array([0.744, 0.800, 0.142])

#Our function
fun = lambda x: np.sum(x*cost)

#Our conditions
cond = ({'type': 'eq', 'fun': lambda x: np.sum(x) - 100},
        {'type': 'ineq', 'fun': lambda x: np.sum(p*x) - 24},
        {'type': 'ineq', 'fun': lambda x: np.sum(e*x) - 76},
        {'type': 'ineq', 'fun': lambda x: -1*x[2] + 2})


bnds = ((0,100),(0,100),(0,100))
guess = [20,30,50]
opt.minimize(fun, guess, method='SLSQP', bounds=bnds, constraints = cond)

It should be noted that eq conditions should be equal to zero, while ineq functions will return true for any values greater then zero.

We obtain:

  status: 0
 success: True
    njev: 4
    nfev: 21
     fun: 97.884100000000345
       x: array([ 40.3,  57.7,   2. ])
 message: 'Optimization terminated successfully.'
     jac: array([ 1.80000019,  0.43300056,  0.18000031,  0.        ])
     nit: 4

Double check the equalities:

output = np.array([ 40.3,  57.7,   2. ])

np.sum(output) == 100
True
round(np.sum(p*output),8) >= 24
True
round(np.sum(e*output),8) >= 76
True

The rounding comes from double point precision errors:

np.sum(p*output)
23.999999999999996
share|improve this answer
    
Fantastic! I was losing my mind trying to set the conditions and different bounds to each variable. Your explanations was clear. Another question: When I use >= contraints: {'type': 'ineq', 'fun': lambda x: np.sum(px) - 24}, if i use <= is: {'type': 'ineq', 'fun': lambda x: 24 - np.sum(px)}, Right? What is the effect of: guess = [20,30,50]? For this example do you see any advantage at use of "bounded" (minimize_scalar) method? –  Martha Morrigan Oct 30 '13 at 15:09
    
I mean, minimize_scalar for a problem with 20 or more variables and constraints. Tyvm! –  Martha Morrigan Oct 30 '13 at 15:28
    
@MarthaMorrigan The inequalities that you posted look correct. The program does not automatically generate an initial guess - as everything you have shown is linear this is not a big deal, but often when minimizing nonlinear equations different starting points will lead to different local minima on the equations hypersurface. I have not used minimize_scalar before, but it appears to be more limited then the general minimize function. I suggest simply trying it for the exact problem you have. –  Ophion Oct 30 '13 at 16:31
    
Ok. I understood. Thanks again for the quick answer. –  Martha Morrigan Nov 1 '13 at 15:37

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