Linear Programming:PRESENTATION IN TABULAR FORM - (SIMPLEX TABLE)

<< Linear Programming:SIMPLEX METHOD, Simplex Procedure

Linear Programming:ARTIFICIAL VARIABLE TECHNIQUE >>

Operations Research (MTH601)

118

Now a question may arise whether the above solution constitutes the best or optimal solution.

Examining the objective function

Z + 2 S2 + 3 S3 = 240,

we observe that the coefficients of the non-basic variables S2 and S3 are positive on the left hand side and this is the

indication to stop the iteration. Hence we conclude that Z = 240 will be the maximum value of Z and the solution set

can be written as

Z* =240

x = 30

y = 30

S1 = 40

S2 = 0

S3 = 0

PRESENTATION IN TABULAR FORM - (SIMPLEX TABLE)

The relevant information of first example may be presented in a concise form as what we call 'Simplex

table' instead of writing down th set of equations in full symbols for the variables in each of the equations. The given

linear programming problem is expressed in a standard form including slack variables. Then we write the

coefficients of the variables and the right hand side in the table.

The above example is presented in the following tabular form. This is the initial table.

RHS

Ratio

Equation

Basic

Coefficient of

No.

Variable

-3

-5

∞

Solution:

Z = 0, S1 = 40, S2 = 30, S3 = 60, x = y = 0

The basic procedure when using the simplex table is the same as before. We give below the steps of the

simplex method that would be applied to prepare the next table from the initial table.

STEP 1

To select the entering basic variable: Consider the first row corresponding to the equation 0 of the table. If the

problem is one to maximize the effectiveness (profit), the variable with the most negative coefficient is selected as

118

Operations Research (MTH601)

119

the new entering basic variable. The column corresponding to the most negative coefficient -5 is 'y' and the same

is marked as a key column indicating that y is the new entering basic variable.

STEP 2

To select the leaving basic variable: Now consider all the rows except the first row. Formulate the ratio in each

row by taking right hand side of each row and dividing by the corresponding element of the key column. The ratios

in this example are 40/0 = ∞, 30/1 = 30, 60/1 = 60. Select the least non-negative ratio. In this example the minimum

non-negative ration corresponds to the row 2 indicating that S2 is the leaving basic variable and this row containing

S2 as the basic variable is marked as a key row. The element at the intersection of key column and key row is called

the key number or pivot number. In this example the key number is 1. If this is not 1, the same can be made 1 by

dividing the same row suitably.

STEP 3

Elimination of coefficients in the key column: Gauss Jordan elimination requires that all the elements in the key

column except the key row should vanish. Suitably multiplying coefficients of the key row and adding the same to

the corresponding coefficients of the other rows achieve this result.

In this example, multiply the key row by 5 and add this resulting row to the row 0. To get rid of the coefficient of y

in the second row, next multiply the key row by 0 and add to the row 1 and similarly multiply the key row by -1 and

add to the row 3 to eliminate the coefficient of y in the third row. So all the key column elements are thus made 0 in

all the rows except the key row. The resulting table is presented. Note that y has entered the basis and S2 has left.

This is the first iteration

y enters the basis and S2 leaves the basis

Iteration I:

RHS

Ratio

Solution

Eqn.

Basic

Coefficient of

S1 S2

No.

Variable

-3

150

Z=150

S1=40

∞

y=30

-1

S3=30

STEP 4

Further improvement of solution: After every iteration, look at the objective function row (row 0). Scan if there is

any negative coefficients among variables in this row for a maximization problem. If there is a negative coefficient,

this is a clear indication that the problem has not reached the maximum value. Still there is a scope of improving the

existing solution. In this example, we have the coefficient of x in the objective function row as -3 (a negative)

indicating that x can be selected as the new entering basic variable. Mark this column as key column and another

iteration is required. So find the ratio in each of the rows 1, 2 and 3. We have, the ratios 40, ∞ and 30 as indicated in

the table under the column ratio. Select the row corresponding to least non-negative value (i.e.) 30, (row 3). So S3 is

the leaving variable and this key row is marked and the same procedure of eliminating the coefficients of x in the

119

Operations Research (MTH601)

120

key column is performed by multiplying the key row by 3, -1 and 0 and adding to the row 0, 1 and 2

respectively. The result is presented in the table below.

STEP 5

Stopping rule: The row 0 has all coefficients of the variables as non-negative. If there is no negative coefficient in

this row, this is an indication that the problem has reached the maximum value and this is the optimal solution to the

linear programming problem.

Note: If the problem is one of minimization subject to constraints of < sign, the criterion for selecting the entering

variable is to pick the variable in the objective row with the most positive coefficient. It all of them are negative or

0, this suggests that the present solution is the optimum.

120

Operations Research (MTH601)

121

REVIEW QUESTIONS

A manufacturer has two products P1 and P2 both or which are produced in two steps by machines

M1 and M2. The process times per hundred for the products on the machines are:-

Products

Contribution

(per 100 units)

Rs. 10

Rs. 5

Available hrs

100

The manufacturer is in a market upswing and can sell as much as he can produce of both products.

Formulate the mathematical model and determine optimum product mix using simplex method.

The ABC company, a manufacturer of test equipment has three major departments for its

manufacture of X-10 model and X-20 model. Monthly capacities are given as follows:-

Time required

per unit

Hours available

X-10 Model

X-20 Model

this month

Main Frame

4.0

2.0

1,600

Department

Electrical Wiring

2.5

1.0

1,200

Department

Assembly Department

4.5

1.5

1,600

The contribution of the X-10 model is Rs. 40/- each and the contribution of the X-20 model is Rs. 10/- each.

Assuming that the company can sell any quantity of either product due to favorable conditions, find:

(i) the optimal output for both models with the help of simplex method

(ii) the highest possible contribution for this month.

(iii) the slack time in the three departments.

A manager produces three items A, B and C. He has the possibility of applying two strategies -

produce all the three items or any two of them. Products A and C pass through shops I and II, whereas B is

further processed in shop III. Each shop has limited available hours. Hours available in shops I, II and III

are 162 hours, 189 hours and 5 hours respectively. Profit per unit from A, B and C is Rs. 27/-, Rs. 29/- and

Rs. 25/- respectively. The following table gives the processing time of different items in different shops.

Items

Shops

121

Operations Research (MTH601)

122

III

Find the optimum production of A, B and C so as to maximize profit.

The ABC manufacturing company can make two products P1 and P2. Each of the products requires

time on a cutting machine and a finishing machine.

Product

Cutting hours (per unit)

Finishing hours (per unit)

Profit per unit

Rs. 6

Rs. 4

Maximum sales (unit per week)

200

The number of cutting hours available per week is 390 and number of finishing hours available per week is

810. How much should be produced of each product in order to achieve maximum profit for the company?

A manufacturer can produce three products A, B and C which pass through different machines M1,

M2 and M3. Available machines for each product and the requirement of machine time for each product is

given in the matrix below.

Machine time

Products

Available time

in hours

1,900

2,100

1,500

If the profit of each unit of A, B and C is respectively Rs. 5, Rs. 4 and Rs. 6, find how many units of each

product should be produced so that the profit will be maximum.

A firm produces 3 products A, B and C using same type of materials L, M, and N. The specific

consumption of each material for unit production is given in the table. The profits of A, B and C are

respectively Rs. 70, Rs. 50 and Rs. 60.

Material

Quantity required per unit

Available

of production

Material

240

160

122

Operations Research (MTH601)

123

(a)

Find the suitable production programme so as to maximize the profit.

(b)

What type of surplus material would be available? Can you utilize materials?

(c)

Find the production pattern (revised) and profit theorem.

A material manufacturing firm has discontinued production of a certain unprofitable product line.

This created considerable excess production capacity. Management is considering to devote this excess

capacity to one or more of three products; call them products 1, 2 and 3. The available capacity on the

machines which limit output is summarized in the following table.

Available time

Machine type

(in machine-hour per week)

Milling machine

250

Lathe

150

Grinder

The number of machine-hours required for each unit of the respective products is given below.

Productivity (in machine hours per unit)

Machine type

Product 1 Product 2

Product 3

Milling machine

Lathe

Grinder

The unit profit would be Rs. 20, Rs. 6 and Rs. 8 respectively for products 1, 2 and 3. Find how much of

each product the firm should produce in order to maximize profit.

A factory produces three products, which are processed through three different stages. The time

required to manufacture one unit of each of the three products and the daily capacity of the stages are given

in the following table.

Time per unit in minutes

Stage capacity

Stage

Product 1 Product 2 Product 3

(minutes)

430

460

420

Profit per

unit (Rs.)

(i)

Set the data in a simplex table.

(ii)

Find the table of optimum solution.

(iii)

State from the tale-maximum profit, production pattern and surplus capacity of any stage.

123

Operations Research (MTH601)

124

(iv)

What is the meaning of the shadow price? Where is it shown in the table? Explain it in respect

of resources of stages having

shadow price.

(v)

How many units of other resources will be required to completely utilize the surplus resource?

Solve the following problem using simplex method:

Maximize

x0 = 2x1 + 3x2 + 4x3

Subject to

2x1 + x2 + 2x3 ≤ 50

x1 + 3x2 + x3 ≤ 25

x1 + 2x2 + x3 ≤ 26

x2 , x3 ≥ 0

x1 ,

10.

A furniture company can produce four types of chairs. Each chair is first made in the carpentry

shop and then varnished, waxed and polished in the finishing shop. Manhours required in each shop are:

Chair type

Carpentry shop

Finishing shop

Contribution per

chair-Rs.

Total number of man-hours available per month in carpentry and finishing shops are 6000 and 4000

respectively. Assuming abundant the number of chairs of different type produced so that profit is

maximized using the simplex method.

11.

A stereo equipment manufacturer can produce two models A and B of 40 and 80 watts total music

power each. Each model passes through three different manufacturing divisions 1, 2 and 3 where model A

takes 4, 2.5 and 4.5 hrs each and model B takes 2, 1 and 1.5 hrs each. The three divisions have a maximum

of 1600, 1200 and 1600 hours every month respectively. Model A gives a contribution of Rs. 400 each and

B gives Rs. 100 each. Assuming abundant product demand, find out the optimum product mix and the

maximum contribution through simplex method.

12.

A company produces three products P, Q and R form three raw materials A, B and C. One unit of

product P requires 2 units of A and 3 units B. A unit of product Q requires 2 units of B and 5 units of C and

one unit of product R requires 3 units of A, 2 units of B and 4 units of C. The company has 8 units of

material A, 10 units of material B and 15 units of material C available to it. Profits per unit of products P, Q

and R are Rs. 3, Rs. 5 and Rs. 4 respectively.

a) Formulate the problem mathematically.

b) How many units of each product should be produced to maximize profit?

13.

A pharmaceutical company has 100 kg of A, 180 kg of B and 120 kg of C available per month.

They can use these materials to make three products namely 5-10-5, 20-5-10, where the numbers in each

124

Operations Research (MTH601)

125

case represent the percentage by weight of A, B and C respectively in each of the product. The cost of

the raw materials are given below.

Ingredient

Inert Ingredient

Cost per Kg (Rs.)

Selling price of these products are Rs. 40.5, Rs. 43 and Rs. 45/kg respectively. There is a capacity

restriction that the product 5-10-5 cannot be produced more than 30 kg per month. Determine how much of

each product they should product they should to maximize their monthly profit.

125

Operations Research (MTH601)

126

14.

Consider the following linear programming problem:

Maximize

x0 = 3x1 + 2x2 + 5x3

Subject to

x1 + 2x2 + 2x3 ≤ 8

3x1 + 2x2 + 6x3 ≤ 12

2x1 + 3x2 + 4x3 ≤ 12

x3 ≥ 0

x1 ,

x2 ,

(i)

Solve this problem by simplex method.

(ii)

Does this problem have an alternative optimal solution?

(iii)

The validity of one of the steps in simplex method becomes questionable as you work out this

problem. What is this step?

15.

An aviation fuel manufacturer sells two types of fuel, A and B. Type A fuel is 25 per cent grade I

petrol, 25 per cent grade II petrol and 50 per cent grade III petrol. Type B fuel is 50 per cent grade III

petrol. Type B fuel is 50 per cent grade II petrol and 50 percent grade III petrol. Available for production

are 2000 liters/hour of grade I and 800 liters/hour of grade II and III. The cost of petrol is Rs. 3 per litre for

grade I, Rs. 6 per litre for grade II and Rs. 5 per litre for grade III. Type A can be sold for Rs. 7.5 per litre

and type B for Rs. 9.00 per litre. How much of each fuel should be made?

16.

A manufacturer uses three raw products a, b, c priced at 30, 50 and 120 rupees per kg respectively.

He can make three different products A, B and C, which can be sold at 90, 100 and 120 rupees per kg

respectively. The raw products can be obtained only in limited quantities, namely 20, 15 and 10 kg per day.

Given 2 kg of a plus 1 kg of b plus 1 kg c will yield 4 kg of A, 3 kg of a plus 2 kg of b plus 2 kg of c will

yield 7 kg of B, 2 kg of b plus 1 kg of c will yield 3 kg of C.

Make a production plan, assuming the order and cost are not influenced by the choice among the

alternatives. Solve the problem by simplex method.

126

Table of Contents: