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I need to implement a solver for linear programming problems. All of the restrictions are <= ones such as

5x + 10y <= 10

There can be an arbitrary amount of these restrictions. Also , x>=0 y>=0 implicitly.

I need to find the optimal solutions(max) and show the feasible region in matplotlib. I've found the optimal solution by implementing the simplex method but I can't figure out how to draw the graph.

Some approaches I've found:

  1. This link finds the minimum of the y points from each function and uses plt.fillBetween() to draw the region. But it doesn't work when I change the order of the equations. I'm not sure which y values to minimize(). So I can't use it for arbitrary restrictions.
  2. Find solution for every pair of restrictions and draw a polygon. Not efficient.

3 Answers 3

18

An easier approach might be to have matplotlib compute the feasible region on its own (with you only providing the constraints) and then simply overlay the "constraint" lines on top.

# plot the feasible region
d = np.linspace(-2,16,300)
x,y = np.meshgrid(d,d)
plt.imshow( ((y>=2) & (2*y<=25-x) & (4*y>=2*x-8) & (y<=2*x-5)).astype(int) , 
                extent=(x.min(),x.max(),y.min(),y.max()),origin="lower", cmap="Greys", alpha = 0.3);


# plot the lines defining the constraints
x = np.linspace(0, 16, 2000)
# y >= 2
y1 = (x*0) + 2
# 2y <= 25 - x
y2 = (25-x)/2.0
# 4y >= 2x - 8 
y3 = (2*x-8)/4.0
# y <= 2x - 5 
y4 = 2 * x -5

# Make plot
plt.plot(x, 2*np.ones_like(y1))
plt.plot(x, y2, label=r'$2y\leq25-x$')
plt.plot(x, y3, label=r'$4y\geq 2x - 8$')
plt.plot(x, y4, label=r'$y\leq 2x-5$')
plt.xlim(0,16)
plt.ylim(0,11)
plt.legend(bbox_to_anchor=(1.05, 1), loc=2, borderaxespad=0.)
plt.xlabel(r'$x$')
plt.ylabel(r'$y$')

enter image description here

4
  • I a total noob when it comes to these things so I hope you don't mind the questions. I haven't used any sort of casting in python. Is the .asType() for generating an array of 0s and ones based on whether the point follows the restrictions?
    – Arturo
    Commented Jul 13, 2019 at 9:40
  • 1
    @Arturo If you evaluate the inequalities, you will see that python (actually, nympy) returns an array with True/False entries that plt.imshow does not understand. With .astype(int), the entries are translated to 0/1's that imshow understands.
    – Stelios
    Commented Jul 13, 2019 at 9:47
  • I'm aware np comes from numpy, but where would I get plt?
    – Lori
    Commented Feb 18, 2022 at 0:15
  • 1
    @Lori import matplotlib.pyplot as plt
    – Stelios
    Commented Feb 18, 2022 at 2:48
3

This is a vertex enumeration problem. You can use the function lineqs which visualizes the system of inequalities A x >= b for any number of lines. The function will also display the vertices on which the graph was plotted.

The last 2 lines mean that x,y >=0

from intvalpy import lineqs
import numpy as np

A = -np.array([[5, 10],
               [-1, 0],
               [0, -1]])
b = -np.array([10, 0, 0])

lineqs(A, b, title='Solution', color='gray', alpha=0.5, s=10, size=(15,15), save=False, show=True)

Visual Solution

Visual Solution Link

0

I created a Jupyter notebook example with UI sliders imported from ipywidgets, that allows the user to try various "what-if" scenarios.

GitHub: https://github.com/jbonfardeci/linear-programming

Google Colab notebook: https://colab.research.google.com/drive/1NLV0RsZdRUUDbd-_OCkqCAjZEXA3UwKW?usp=sharing

Visually Solve Linear Programming Problem

2
  • Those wishing to try this as an active Jupyter .ipynb file can click here to get a session right in your browser served via the MyBinder service with all the necessary packages already installed and working so you can just go ahead and do 'Run' > 'Run All Cells' to try it out.
    – Wayne
    Commented Jan 21 at 17:06
  • I updated the link to a notebook in Google Colab. Commented Jan 21 at 21:36

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