Operations Management (McGraw-Hill Series in Operations and Decision Sciences)
Operations Management (McGraw-Hill Series in Operations and Decision Sciences)
12th Edition
ISBN: 9780078024108
Author: William J Stevenson
Publisher: McGraw-Hill Education
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Chapter 18, Problem 1P

a)

1)

Summary Introduction

To determine: The system utilization rate.

Introduction: System utilization refers to percentage amount of capacity which is utilized or we can say that actual output is divided by potential output. It is operational metric for business which indicates aggregate productive capacity.

It reflects the ratio of demand to capacity or supply, it is also commonly known as Capacity utilization rate.

a)

1)

Expert Solution
Check Mark

Answer to Problem 1P

The system utilization rate is 0.600.

Explanation of Solution

Given information:

λ=3customer/hours

μ=5customer/hours

M=1

Formula,

ρ=λMμ

Where,

System utilization rate denoted by ρ

Demand rate (measured as arrival) denoted by λ

Supply rate (measured as service) denoted by Mμ

Calculation of the system utilization:

ρ=λMμ=31×5=0.6000

Therefore, system utilization rate is 0.6000.

1)

Summary Introduction

To determine: The system utilization rate.

Introduction: System utilization refers to percentage amount of capacity which is utilized or we can say that actual output is divided by potential output. It is operational metric for business which indicates aggregate productive capacity.

It reflects the ratio of demand to capacity or supply, it is also commonly known as Capacity utilization rate.

1)

Expert Solution
Check Mark

Answer to Problem 1P

The system utilization rate is 0.600.

Explanation of Solution

Given information:

λ=3customer/hours

μ=5customer/hours

M=1

Formula,

ρ=λMμ

Where,

System utilization rate denoted by ρ

Demand rate (measured as arrival) denoted by λ

Supply rate (measured as service) denoted by Mμ

Calculation of the system utilization:

ρ=λMμ=31×5=0.6000

Therefore, system utilization rate is 0.6000.

2)

Summary Introduction

To determine: The average number customers waiting for service in line.

2)

Expert Solution
Check Mark

Answer to Problem 1P

Average number of customers waiting in line (Lq) is 0.9000.

Explanation of Solution

Explanation

Given information:

λ=3customer/hours

μ=5customer/hours

Formula as per single server model of average number customers waiting for service in line

Lq=λ2μ(μλ)

Where,

Lq is denoted by average number customers waiting for service in line

Demand rate (measured as arrival) denoted by λ

Supply rate per server denoted by μ

Calculation of Average number of customers waiting in line (Lq):

Lq=λ2μ(μλ)=325(53)=0.900

Therefore, average number of customers waiting in line (Lq) is 0.9000.

3)

Summary Introduction

To determine: Average number of customers waiting time.

3)

Expert Solution
Check Mark

Answer to Problem 1P

The average number customers waiting time ( Wq ) is 0.3000.

Explanation of Solution

Given information:

λ=3customer/hours

Formula as per single server model of average number customers waiting for service in line:

Wq=Lqλ

Where,

Lq is denoted by average number customers waiting for service in line

Wq is denoted by average number customers waiting time

Demand rate (measured as arrival) denoted by λ

Calculation of Average number of customers waiting in line ( Wq ):

Wq=Lqλ=0.90003=0.3000

Therefore, average number customers waiting time ( Wq ) is 0.3000.

b)

1)

Summary Introduction

To determine: The average number of customer waiting for repairs.

b)

1)

Expert Solution
Check Mark

Answer to Problem 1P

Average number of customers waiting in line (Lq) is 2.250.

Explanation of Solution

Given information:

λ=3 repair calls/8-hour day

Mean service time: 2 hours

M =1

Calculation of μ

μ=productivehoursmeanservicetime=82=4repaircall/8-hour day

Formula as per single server model of average number customers waiting for service in line:

Lq=λ2μ(μλ)

Where,

Lq is denoted by average number customers waiting for service in line

Demand rate (measured as arrival) denoted by λ

Supply rate per server denoted by μ

Calculation of Average number of customers waiting in line (Lq):

Lq=λ2μ(μλ)=324(43)=2.250

Therefore, Average number of customers waiting in line (Lq) is 2.250.

1)

Summary Introduction

To determine: The average number of customer waiting for repairs.

1)

Expert Solution
Check Mark

Answer to Problem 1P

Average number of customers waiting in line (Lq) is 2.250.

Explanation of Solution

Given information:

λ=3 repair calls/8-hour day

Mean service time: 2 hours

M =1

Calculation of μ

μ=productivehoursmeanservicetime=82=4repaircall/8-hour day

Formula as per single server model of average number customers waiting for service in line:

Lq=λ2μ(μλ)

Where,

Lq is denoted by average number customers waiting for service in line

Demand rate (measured as arrival) denoted by λ

Supply rate per server denoted by μ

Calculation of Average number of customers waiting in line (Lq):

Lq=λ2μ(μλ)=324(43)=2.250

Therefore, Average number of customers waiting in line (Lq) is 2.250.

2)

Summary Introduction

To determine: The system utilization rate.

Introduction: It reflects the ratio of demand to capacity or supply, it is also commonly known as Capacity utilization rate.

2)

Expert Solution
Check Mark

Answer to Problem 1P

The system utilization rate is 0.750.

Explanation of Solution

Given information:

λ=3customer/hours

μ=4 repair calls/8-hour day

M=1

Formula,

ρ=λMμ

Where,

System utilization rate denoted by ρ

Demand rate (measured as arrival) denoted by λ

Supply rate (measured as service) denoted by Mμ

Calculation of the system utilization:

ρ=λMμ=31×4=0.750

Therefore, system utilization rate is 0.750.

3)

Summary Introduction

To determine: The idle time.

3)

Expert Solution
Check Mark

Answer to Problem 1P

The idle time is 2hours per day.

Explanation of Solution

Calculation of the idle time:

Idletimepercentage=1Systemutilization=10.75=25.00%

Idletimehours=Idletimepercentage ×working hour perday=25%×8hours/day=2hours

Therefore, idle time per day per hours is 2hours per day.

4)

Summary Introduction

To determine: Probability of two or more customers in the system.

4)

Expert Solution
Check Mark

Answer to Problem 1P

The probability of two or more customers in the system is 0.5625.

Explanation of Solution

Step 1: Calculate the probability of less than two:

P<2=1(λμ)=1(34)2=10.5625=0.4375

Therefore, probability of less than two is 0.4375.

Step 2: Calculation probability of two or more than customer in the system:

P2=1P<2=10.4375=0.5625

Therefore, probability of less than two is 0.5625.

c)

1)

Summary Introduction

To determine: The system utilization rate.

c)

1)

Expert Solution
Check Mark

Answer to Problem 1P

The system utilization rate is 0.750.

Explanation of Solution

Given information

λ=18customer/hours

μ=12customer/hours

M=2

Formula:

ρ=λMμ

Where,

System utilization rate denoted by ρ

Demand rate (measured as arrival) denoted by λ

Supply rate (measured as service) denoted by Mμ

Calculation of the system utilization:

ρ=λMμ=182×12=0.750

Therefore, system utilization rate is 0.7500.

1)

Summary Introduction

To determine: The system utilization rate.

1)

Expert Solution
Check Mark

Answer to Problem 1P

The system utilization rate is 0.750.

Explanation of Solution

Given information

λ=18customer/hours

μ=12customer/hours

M=2

Formula:

ρ=λMμ

Where,

System utilization rate denoted by ρ

Demand rate (measured as arrival) denoted by λ

Supply rate (measured as service) denoted by Mμ

Calculation of the system utilization:

ρ=λMμ=182×12=0.750

Therefore, system utilization rate is 0.7500.

2)

Summary Introduction

To determine: Average number of customers in the system (Ls).

2)

Expert Solution
Check Mark

Answer to Problem 1P

Average number of customers in the system (Ls) is 3.429.

Explanation of Solution

Step 1: Calculation of the average number of customer served

r=λμ=1812=1.5

Therefore average number of customer served is 1.5.

Step 2: find the value of Lq

Given information:

λμ = 1.5 and M is 2

Then, from Infinite-source values table we find that value for Lq is 1.929.

For reference:

Operations Management (McGraw-Hill Series in Operations and Decision Sciences), Chapter 18, Problem 1P

Step 3Calculation of the average number of customers in the system (Ls)

Ls=Lq+λμ=1.929+1812=1.929+1.5=3.429

Therefore, the average number of customers in the system (Ls) is 3.429.

3)

Summary Introduction

To determine: Average time customers wait in line for service (Wq).

3)

Expert Solution
Check Mark

Answer to Problem 1P

Average time customers wait in line for service (Wq).is 0.107.

Explanation of Solution

Wq=Lqλ=1.92918=0.107

Therefore, the average time customers wait in line for service (Wq).is 0.107.

4)

Summary Introduction

To determine: The average waiting time for an arrival not immediately served (hours) (Wa).

4)

Expert Solution
Check Mark

Answer to Problem 1P

The average waiting time for an arrival not immediately served (hours) (Wa) is 0.167.

Explanation of Solution

Calculation of average waiting time for an arrival not immediately served (hours) (Wa):

Wa=1Mμλ=1(2×12)18=12418=16=0.167

Therefore, average waiting time for an arrival not immediately served (hours) (Wa) is 0.167 hours.

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