Waiting Line Models
(Queuing Theory)
© 2013 Lew Hofmann
Examples of Lines in Operations Management
• Assembly lines
• Production lines
• Trucks waiting to unload or load
• Workers waiting for parts
• Customers waiting for products
• Broken equipment waiting to be fixed
• Customers waiting for service
© 2013 Lew Hofmann
Why We Analyze Waiting Lines
Lines cost a business money.
The resources in a line (people and/or
material) are idle and thus unproductive.
The resources needed to process a line
(cashiers, dock workers, equipment, etc.)
cost a business money.
There is an ideal length for a line that
minimizes the total cost of the line..
© 2013 Lew Hofmann
Costs The costs of waiting in line
Paying idle employees while they are in line waiting for something they need. (waiting for parts, supplies, deliveries, etc.)
Unusable (unproductive) equipment awaiting repairs• EG: Broken assembly line machinery.
Losing customers because of long lines• Reneging: Customers get tired of waiting and leave
• Balking: Customers see a long line and don’t get in line.
The cost of providing service to the line Paying people to service the customers in line Customers can be people, machines, or other objects needing service.
© 2013 Lew Hofmann
Cost of Providing Service
• Paying repairmen to fix broken machines
• Paying dock workers to load and unload trucks
• Paying customer-service people
• Using more production people to speed up the line
• Leasing of service equipment and facilities
• Paying checkout cashiers
© 2013 Lew Hofmann
Queuing System Costs
Number of Servers
Costs
Cost of Servicegoes up as you pay for more servers.
Costs of Waitinggoes down as service improves.
Total Cost
Optimal # of servers
Note that the lowest cost system requires some customer waiting.
Fewer servers often means longer waiting for customers. Many servers
means little or no waiting, but higher service costs.
© 2013 Lew Hofmann
What Queuing Models Tell Us.
• Average number of customers in line.
• Average time in line for a customer.
• Average number of customers in the system at any time.
• Average time in the system for a customer.
• Probability of n number of customers in the system at any given time.
• NOTE: “In The System” includes customers who are waiting plus and the customers being served.
© 2013 Lew Hofmann
ARRIVAL SYSTEM(How customers arrive)
QUEUE(The nature of the waiting line or lines of customers)
The Waiting Line System
SERVICE FACILITY(How customers progress through the service facility)
© 2013 Lew Hofmann
Waiting Line Models
Customer population
Served customers
Arrival System
Service System
Waiting line (Queue)
Priority rule
Service facilities
The sequence in which customers are admitted into the service facility.
© 2013 Lew Hofmann
Arrival System
• Arrival Populations are either…
• Limited (EG: Only people age 21 or over.)
• Unlimited (EG: cars arriving at a toll booth)
• Arrival Patterns are either…
• Random (Each arrival is independent)
• Scheduled (EG: Doctor’s office visits)
• Behavior of the Arrivals
• Balking (Seeing a long line and avoiding it.)
• Reneging (Get tired of waiting and leave the line)
• Jockeying (Switching lines)
© 2013 Lew Hofmann
The Queue (line)
• Queue Length is either..
• Unlimited (EG: cars in line at a toll booth)
• Limited (Finite) EG: # of e-mail messages allowed.
• Queue Discipline (order of service)
• FIFO (First-In, First-Out)
• LIFO (Last-In, First-Out)
• SIRO (Service In Random Order)
• Priority
© 2013 Lew Hofmann
The Service Facility
• Channels are the paths (ways to get through
the system) after getting in line?
• EG: McDonalds drive-thru is one channel.
• Phases are the number of stops a customer must make, after getting in line?
(Single-phase means only one stop for service.)
• McDonalds drive-thru is a three-phase system:
Order Pay Pick-up
© 2013 Lew Hofmann
Single-channel, Single-phaseOne way through the system
and one stop for service
Service Facility
© 2013 Lew Hofmann
Multi-channel, Single-phase
Service Facility
Service Facility
Once in line, you have at least two choices of how to get through the system, but only one stop.
© 2013 Lew Hofmann
Multi-channel, Multi-phase
Service Facility
Service Facility
Service Facility
Service Facility
Once in line, you have at least two choices (channels) of how to get through the system and at least two stops (phases).
© 2013 Lew Hofmann
Four Single-channel, Single-phase Systems(Once in line, you only have one channel and one stop.)
Service Facility
Service Facility
Service Facility
Service Facility
© 2013 Lew Hofmann
One, Multi-channel, Single-Phase System (Once in line you have four possible paths through the system, but only one stop.)
Service Facility
Service Facility
Service Facility
Service Facility
© 2013 Lew Hofmann
Assumptions We Will Use• The Rate of Service must be faster than the Rate of
Arrivals. (It is unsolvable if customers arrive faster than they can be served.)
• Always enter the service rate for 1 server. The model will compute the total service rate based on the number of servers.
• FIFO (First In, First Out) (Customers are served in the order they arrive.)
• Arrivals are unlimited (infinite)
• Arrivals are random rather than scheduled.
• Customers arrive independently of each other.
• Service times can vary from one customer to another, and are independent of each other. (Customers may have different service needs and times.)
© 2013 Lew Hofmann
Queuing ProblemAt a large Naval Ship Repair Facility mechanics have to make frequent trips to the tool crib for parts and specialized equipment. Arrivals are infinite (unrestricted) since mechanics can come as often as need, even though the population of customers is finite.)
Records indicate that the tool crib serves an average of 18 mechanics each hour, but an attendant is capable of serving 20 per hour. If mechanics are paid $30 per hour and the tool crib attendants make $9 per hour, would it be more cost effective to have one or two attendants in the tool crib?
The service rate is always the average number for one server, regardless of how many servers there are in the system. In this case the service rate of 20 is higher than the arrival rate of 18. If the service rate had been 10 customers per server, you would need at least two servers.
© 2013 Lew Hofmann
1st
Attendant
2nd
Attendant
Single
Attendant
Which system is less expensive?
(It depends on the relative cost of service versus cost of waiting.)
© 2013 Lew Hofmann
Data-Entry Information for POM/QM
I ran the POM-QM model using two servers, but I could have run it with any number of servers since you always enter the service rate for one server. The POM-QM model will do the computations for more than one server.
1st
Attendant
2nd
Attendant
Single
Attendant
Mechanics (customers) arrive at an average of 18 per hour and are paid $30 per hour.
One attendant can serve 20 mechanics/customers per hr.and is paid $9 per hour.
© 2013 Lew Hofmann
Select the Module
Select the M/M/s Model
© 2013 Lew Hofmann
Select Cost Analysis and Enter the Title
© 2013 Lew Hofmann
Always enter the Service rate for 1 server!
© 2013 Lew Hofmann
• Average # customers in the system
• Average time spent in the system
• Average time spent in line
• Average # of customers in line
Results for 2 serversMake sure you use the M/M model.
© 2013 Lew Hofmann
Find the optimal # of servers
Lowest Cost is $51.86 using two servers.
• In this problem, you would have gotten this screen regardless of how many servers you used for the input, because the service rate for one server exceeded the arrival rate.
• The single-server rate times the number of servers you enter must exceed the arrival rate. If the single-server rate in this problem had been six per hour instead of 20 per hour, you would have had to enter at least 4 servers. (Three servers would have served 18 per hour, which does not exceed the arrival rate of 18.)
© 2013 Lew Hofmann
The probability that 4 or fewer mechanics are in the system is 97%
Probability that the system is idle (no customers) is 38%
© 2013 Lew Hofmann
# of Servers
1 2
What the Model Tells Us…
• Average # customers in the
system
• Average time in the system
(min.)
• Average # customers in line
• Average time in line (min.)
• Probability that the system is
idle
9
1.13
30
3.76
8.1
0.23
27
0.76
10%
38%
Once you know the optimal # of servers, make sure you run it again for that many servers in order to get the right data. But always enter the service rate for one server, regardless of how many servers.
Note: You need to run the model with 1 server if you want the info for 1 server, and run it using 2 servers to get the info for 2 servers.
© 2013 Lew Hofmann
POM/QM or Excel Solver?
POM/QM will do the cost analysis for you, so it is easier. (Select the “M/M” model.)
You can use the Excel Solver, but it won’t do the cost analysis, so you would need to do that manually.
You also need to run the Excel solver once for each server number you use, and then do a manual cost analysis for each in order to see which number of servers has the lowest cost.
In multiple server problems, you might have to run it for a half-dozen or more scenarios.
© 2013 Lew Hofmann
Excel Solver: 1 Server
© 2013 Lew Hofmann
Manual cost computations for one server (9 customers in the system)
• Mechanics get paid $30 per hourCost of waiting is: $30 x 9 customers in system = $270
• Attendants get paid $9 per hour(Cost of service is thus 1 server x $9 = $9 per hour)
• Total cost of one server is: $270 + $9 = $279
POM-QM model
© 2013 Lew Hofmann
Excel Solver: Two Servers
© 2013 Lew Hofmann
Manual cost computations for Two servers (9 customers in the system)
• Mechanics get paid $30 per hourCost of waiting is: $30 x 1.28 customers in system = $33.84
• Attendants get paid $9 per hourCost of service is: $9 x 2 servers = $18 per hour
• Total cost of two servers is: $18 + $33.84 = $51.84
POM-QM model
© 2013 Lew Hofmann
Homework Assignment
Due next Tuesday
Problem 1: The Auto Repair Center
Problem 2: The Quarry
Use POM/OM or Excel Solver software and submit printouts to support your decisions
© 2013 Lew Hofmann
Auto Repair Center In the service department of a repair shop, mechanics requiring parts for repair or service present their request forms at the parts department counter. The parts clerk fills a request while the mechanic waits.
Mechanics arrive in a random fashion at the rate of 40 per hour, and a clerk can fill requests at the rate of 20 per hour. If the cost for a parts clerk is $6 per hour and the cost for a mechanic is $12 per hour, determine the optimum number of clerks to staff the counter. (Because of the high arrival rate, an infinite source may be assumed.)
Always enter the service rate for one server. The program will do the math once you enter the number of servers. If you enter fewer servers than can handle the arrival needs, the program will give you an error message because the computed service rate must be higher than the arrival rate.
© 2013 Lew Hofmann
The Quarry (no cost analysis in model)You are in charge of a quarry that supplies sand and stone aggregates to construction sites. Empty trucks arrive and wait in line for loading either sand or aggregate. At the loading station they are filled with material, weighted, checked out, and then proceed to a construction site.
Currently 9 empty trucks arrive each hour (on average). In addition to waiting in line, it takes 6 minutes for a truck to be filled, weighed and checked out.
Concerned that trucks are spending too much time waiting and being filled, you evaluate the current situation and compare it to the 2 alternatives below.
Alternative 1: Speed up the loading process and add side boards to the trucks so that more material can be loaded faster. This will improve the speed of loading, but cost $50,000. Since the trucks hold more, their arrival rate would be reduced to 6 per hour and the loading time would be reduced to 4 minutes each.
Alternative 2: Add a second loading station at a cost of $80,000. The trucks would arrive at the current rate of 9 per hour. They would then wait in a common line and the truck at the front of the line would move to the next available loading station. Loading time at each of the stations is 6 minutes.
Which alternative do you recommend? (Select “No Cost” in the POM/QM waiting line model. You must decide which of the three situations would the most cost effective based on time in the system and upgrade costs.
© 2013 Lew Hofmann
Facts About Queuing
QUEUE originally (15th century) referred to the “tail of the beast” or “a tail piece.” (Not to be confused with a piece of tail.)
In the 17th century a queue became “a braid of hair.” Later it was used to refer to a pigtail.
In the 18th century a billiard stick became a queue, later changed to “que” and then to “cue”.
In the early 19th century England, to queue was “to line up.” And that is how it is used today in England.