Post on 19-Dec-2015
1Chapter 4 - Linear Programming: Modeling Examples
Chapter 4
Linear Programming: ModelingExamples
Introduction to Management Science
8th Edition
by
Bernard W. Taylor III
2Chapter 4 - Linear Programming: Modeling Examples
Chapter Topics
A Product Mix Example
A Diet Example
An Investment Example
A Marketing Example
A Transportation Example
A Blend Example
A Multi-Period Scheduling Example
3Chapter 4 - Linear Programming: Modeling Examples
A Product Mix ExampleProblem Definition (1 of 7)
Four-product T-shirt/sweatshirt manufacturing company.
Must complete production within 72 hours
Truck capacity = 1,200 standard sized boxes.
Standard size box holds12 T-shirts.
One-dozen sweatshirts box is three times size of standard box.
$25,000 available for a production run.
500 dozen blank T-shirts and sweatshirts in stock.
How many dozens (boxes) of each type of shirt to produce?
4Chapter 4 - Linear Programming: Modeling Examples
Processing Time (hr) Per dozen
Cost ($)
per dozen
Profit ($)
per dozen
Sweatshirt - F 0.10 36 90
Sweatshirt – B/F 0.25 48 125
T-shirt - F 0.08 25 45
T-shirt - B/F 0.21 35 65
A Product Mix ExampleData (2 of 7)
5Chapter 4 - Linear Programming: Modeling Examples
Decision Variables:
Objective Function:
Model Constraints:
A Product Mix ExampleModel Construction (3 of 7)
6Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.1
A Product Mix ExampleComputer Solution with Excel (4 of 7)
7Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.2
A Product Mix ExampleSolution with Excel Solver Window (5 of 7)
8Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.3
A Product Mix ExampleSolution with QM for Windows (6 of 7)
9Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.4
A Product Mix ExampleSolution with QM for Windows (7 of 7)
10Chapter 4 - Linear Programming: Modeling Examples
Breakfast to include at least 420 calories, 5 milligrams of iron, 400 milligrams of calcium, 20 grams of protein, 12 grams of fiber, and must have no more than 20 grams of fat and 30 milligrams of cholesterol.
Breakfast Food Cal
Fat (g)
Cholesterol (mg)
Iron (mg)
Calcium (mg)
Protein (g)
Fiber (g)
Cost ($)
1. Bran cereal (cup) 2. Dry cereal (cup) 3. Oatmeal (cup) 4. Oat bran (cup) 5. Egg 6. Bacon (slice) 7. Orange 8. Milk-2% (cup) 9. Orange juice (cup)
10. Wheat toast (slice)
90 110 100
90 75 35 65
100 120
65
0 2 2 2 5 3 0 4 0 1
0 0 0 0
270 8 0
12 0 0
6 4 2 3 1 0 1 0 0 1
20 48 12
8 30
0 52
250 3
26
3 4 5 6 7 2 1 9 1 3
5 2 3 4 0 0 1 0 0 3
0.18 0.22 0.10 0.12 0.10 0.09 0.40 0.16 0.50 0.07
A Diet ExampleData and Problem Definition (1 of 5)
11Chapter 4 - Linear Programming: Modeling Examples
x1 = cups of bran cereal
x2 = cups of dry cereal
x3 = cups of oatmeal
x4 = cups of oat bran
x5 = eggs
x6 = slices of bacon
x7 = oranges
x8 = cups of milk
x9 = cups of orange juice
x10 = slices of wheat toast
A Diet ExampleModel Construction – Decision Variables (2 of 5)
12Chapter 4 - Linear Programming: Modeling Examples
Minimize Z =
subject to:
A Diet ExampleModel Summary (3 of 5)
13Chapter 4 - Linear Programming: Modeling ExamplesExhibit 4.5
A Diet ExampleComputer Solution with Excel (4 of 5)
14Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.6
A Diet ExampleSolution with Excel Solver Window (5 of 5)
15Chapter 4 - Linear Programming: Modeling Examples
An Investment ExampleModel Summary (1 of 5)
Kathleen has $70,000 to invest.
Municipal bonds (MB): 8.5%
Certificates of deposit (CD): 5%
Treasury bills (TB): 6.5%
Growth stock fund (GSF): 13%
No more than 20% in municipal bonds
Amount in CD < in other 3 alternatives
At 30% in treasury bills and CD
Ratio in (TB and CD) to (MB and GSF) > 1.2 to 1
16Chapter 4 - Linear Programming: Modeling Examples
Decision Variables:
Maximize Z =
subject to:
An Investment ExampleModel Summary (2 of 5)
17Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.7
An Investment ExampleComputer Solution with Excel (2 of 5)
18Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.8
An Investment ExampleSolution with Excel Solver Window (3 of 5)
19Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.9
An Investment ExampleSensitivity Report (5 of 5)
20Chapter 4 - Linear Programming: Modeling Examples
Budget limit $100,000
Television time for four commercials
Radio time for 10 commercials
Newspaper space for 7 ads
Resources for no more than 15 commercials and/or ads
Exposure (people/ad or commercial)
Cost
Television Commercial
20,000 $15,000
Radio Commercial
12,000 6,000
Newspaper Ad 9,000 4,000
A Marketing ExampleData and Problem Definition (1 of 6)
21Chapter 4 - Linear Programming: Modeling Examples
Decision variables:
Maximize Z =
subject to:
A Marking ExampleModel Summary (2 of 6)
22Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.10
A Marking ExampleSolution with Excel (3 of 6)
23Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.11
A Marking ExampleSolution with Excel Solver Window (4 of 6)
24Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.12
Exhibit 4.13
A Marking ExampleInteger Solution with Excel (5 of 6)
25Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.14
A Marking ExampleInteger Solution with Excel (6 of 6)
26Chapter 4 - Linear Programming: Modeling Examples
Warehouse supply of Retail store demand Television Sets: for television sets:
1 - Cincinnati 300 A - New York 150
2 - Atlanta 200 B - Dallas 250
3 - Pittsburgh 200 C - Detroit 200
Total 700 Total 600
To Store From Warehouse
A B C
1 $16 $18 $11
2 14 12 13
3 13 15 17
A Transportation ExampleProblem Definition and Data (1 of 3)
27Chapter 4 - Linear Programming: Modeling Examples
Decision variables:
Minimize Z =
subject to:
A Transportation ExampleModel Summary (2 of 4)
28Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.15
A Transportation ExampleSolution with Excel (3 of 4)
29Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.16
A Transportation ExampleSolution with Solver Window (4 of 4)
30Chapter 4 - Linear Programming: Modeling Examples
Component Maximum Barrels
Available/day Cost/barrel
1 4,500 $12
2 2,700 10
3 3,500 14
Grade Component Specifications Selling Price ($/bbl)
Super At least 50% of 1
Not more than 30% of 2 $23
Premium At least 40% of 1
Not more than 25% of 3
20
Extra At least 60% of 1 At least 10% of 2
18
A Blend ExampleProblem Definition and Data (1 of 6)
31Chapter 4 - Linear Programming: Modeling Examples
Determine the optimal mix of the three components in each grade of motor oil that will maximize profit. Company wants to produce at least 3,000 barrels of each grade of motor oil.
Decision variables: The quantity of each of the three components used in each grade of gasoline (9 decision variables); xij = barrels of component i used in motor oil grade j per day, where i = 1, 2, 3 and j = s (super), p (premium), and e (extra).
A Blend ExampleProblem Statement and Variables (2 of 6)
32Chapter 4 - Linear Programming: Modeling Examples
Maximize Z =
subject to:
A Blend ExampleModel Summary (3 of 6)
33Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.17
A Blend ExampleSolution with Excel (4 of 6)
34Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.18
A Blend ExampleSolution with Solver Window (5 of 6)
35Chapter 4 - Linear Programming: Modeling ExamplesExhibit 4.19
A Blend ExampleSensitivity Report (6 of 6)
36Chapter 4 - Linear Programming: Modeling Examples
Production Capacity: 160 computers per week 50 more computers with overtime
Assembly Costs: $190 per computer regular time; $260 per computer overtime
Inventory Cost: $10/comp. per week
Order schedule: Week Computer Orders 1 105 2 170 3 230 4 180 5 150 6 250
A Multi-Period Scheduling ExampleProblem Definition and Data (1 of 5)
37Chapter 4 - Linear Programming: Modeling Examples
Decision Variables:
rj = regular production of computers per week j(j = 1 - 6)
oj = overtime production of computers per week j(j = 1 - 6)
ij = extra computers carried over as inventory in week j(j = 1 - 5)
A Multi-Period Scheduling ExampleDecision Variables (2 of 5)
38Chapter 4 - Linear Programming: Modeling Examples
Model summary:
Minimize Z =
subject to:
A Multi-Period Scheduling ExampleModel Summary (3 of 5)
39Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.20
A Multi-Period Scheduling ExampleSolution with Excel (4 of 5)
40Chapter 4 - Linear Programming: Modeling Examples
Exhibit 4.21
A Multi-Period Scheduling ExampleSolution with Solver Window (5 of 5)
41Chapter 4 - Linear Programming: Modeling Examples
Example Problem SolutionProblem Statement and Data (1 of 5)
Canned cat food, Meow Chow; dog food, Bow Chow.
Ingredients/week: 600 lb horse meat; 800 lb fish; 1000 lb cereal.
Recipe requirement: Meow Chow at least half fish; Bow Chow at least half horse meat.
2,250 sixteen-ounce cans available each week.
Profit /can: Meow Chow $0.80; Bow Chow $0.96.
How many cans of Bow Chow and Meow Chow should be produced each week in order to maximize profit?
42Chapter 4 - Linear Programming: Modeling Examples
Step 1: Define the Decision Variables
xij = ounces of ingredient i in pet food j per week, where i = h (horse meat), f (fish) and c (cereal), and j = m (Meow chow) and b (Bow Chow).
Step 2: Formulate the Objective Function
Maximize Z =
Example Problem SolutionModel Formulation (2 of 5)
43Chapter 4 - Linear Programming: Modeling Examples
Step 3: Formulate the Model Constraints
Amount of each ingredient available each week:
Recipe requirements:Meow Chow
Bow Chow
Can Content Constraint
Example Problem SolutionModel Formulation (3 of 5)
44Chapter 4 - Linear Programming: Modeling Examples
Step 4: Model Summary
Maximize Z = $0.05xhm + $0.05xfm + $0.05xcm + $0.06xhb + 0.06xfb + 0.06xcb
subject to:xhm + xhb 9,600 ounces of horse meatxfm + xfb 12,800 ounces of fishxcm + xcb 16,000 ounces of cereal additive- xhm + xfm- xcm 0 xhb- xfb - xcb 0xhm + xfm + xcm + xhb + xfb+ xcb 36,000 ounces
xij 0
Example Problem SolutionModel Summary (4 of 5)
45Chapter 4 - Linear Programming: Modeling Examples
Example Problem SolutionSolution with QM for Windows (5 of 5)
Exhibit 4.24