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Production and Operations
Management Systems
Chapter 5: Inventory Management
Sushil K. Gupta
Martin K. Starr
2014
1
After reading this chapter, you should
be able to:

Explain what inventory management entails.

Describe the difference between static and dynamic inventory
models.

Discuss demand distribution effects on inventory situations.

Differentiate inventory costs by process types.

Describe all costs relevant to inventory models.
2
After reading this chapter, you should
be able to (continued):

Discuss the use of economic order quantity (EOQ) models.

Discuss the use of economic production quantity (EPQ)
models.

Describe the discount model and explain how it indicates when
a discount should be taken.

Perform ABC classification of materials.
3
After reading this chapter, you should
be able to (continued):

Discuss lead-time effects on inventory situations.

Explain order point policies (OPP) and when they are used.

Explain the operation of the periodic inventory model.

Explain the operation of the perpetual inventory model.

Discuss reorder points.

Discuss and calculate safety stocks.

Describe a two-bin system.
4
Types of Inventory Situations
o
o
o
o
o
o
Order repetition—static versus dynamic situations.
Demand distribution—certainty, risk, and uncertainty.
Stability of demand distribution—fixed or varying.
Demand continuity—smoothly continuous or sporadic and
occurring as lumpy demand; independent.
Lead-time distributions—fixed or varying.
Dependent or independent demand.
5
Functions of Inventory
Consider three subsystems of an organization representing the
supplier, manufacturer and the market.
These three subsystems are rigidly connected with each other,
without any inventories, as shown below.
Inventories reduce dependency of one subsystem over the other
in a supply chain.
Suppliers
Manufacturer
Market
6
Functions of Inventory (continued)




Production Planning – level production.
Take advantage of quantity (price) discounts.
Protect against anticipated increase in prices.
Protect against anticipated shortages.
7
Inventory Related Costs
o
o
o
o
o
o
Costs of ordering
Costs of setups and changeovers
Costs of carrying inventory
Costs of discounts
Out-of-stock costs
Costs of running the inventory system
8
Data for Inventory Problems
•
•
•
•
•
•
•
•
•
D: Annual Demand (units per year)
C: Unit Price (purchase price of the item)
S: Ordering or Setup Cost per Order
H: Inventory Holding (Carrying) Cost/unit per year
i: H may be given as i percent of C
TC: Total Annual Cost
TVC: Total Annual Variable Cost
Q: Order Quantity
EOQ: Economic Order Quantity (optimal value of Q)
9
Economic Order Quantity
(EOQ) Model
10
Inventory Level Variations
Suppose Annual Demand
D = 1200
Suppose Q units are purchased
at a time, where,
Q = 600
Q = 400 etc.
Order Size, Q = 600
The figures on the RHS show
inventory variations for
different values of Q assuming
a constant and continuous
demand of 100 units per
month.
Order Size, Q = 400
11
Average Inventory and Number of Orders
Average inventory = Q/2.
Number of orders = D/Q.
Order Size, Q = 400
If Q = 400
Average Inventory
= 400/2 = 200
# Orders = 1200/400 = 3
Average Inventory during the first four months
is (400+0)/2 = 200.
For the next four months it is again (400+0)/2
= 200
Similarly for the last four months, the average
inventory is (400+0)/2 = 200
This means that the average inventory through
out the year is 200.
12
TC and TVC Formulae
Total Annual Cost (TC) = Annual Ordering Cost (D/Q)S +
Annual Holding Cost (Q/2)H+ Annual Purchase Cost (DC)
TC 
D
Q
S
H  DC
Q
2
Total Annual Variable Cost (TVC) = Annual Ordering Cost +
Annual Holding Cost
TVC 
D
Q
S
H
Q
2
Note: Annual purchase cost is not included in TVC.
13
EOQ Formula
In the equations for TC and TVC, the values of D, H, S and C are known.
The only unknown variable is Q. Our objective is to minimize TC.
TC is minimized at that value of Q, where, Annual Ordering Cost = Annual Holding
Cost. See the equation below.
D
Q
S H
Q
2
Solving the above equation for Q, gives the value of EOQ (QO) as shown below.
EOQ 
2 DS
H
14
EOQ Example
Suppose D = 1,200 units, S = $5.00, H = $ 1.20 and C = $ 12.00.
EOQ (QO) for this problem is given below.
Qo =
2∗1200 ∗5
1.2
= 100
15
Graphs of Various Costs
The figure on RHS shows the
graphs of various costs as the
order quantity Q is changed.
The graphs for Annual
Ordering Cost and Annual
Inventory Cost intersect at
EOQ (=100).
16
Costs for Various Order Quantities
Note that minimum cost is
for Q = 100 (EOQ).
Ordering Cost = Inventory
Cost = 60 for Q = 100.
TC can be calculated as
TC = TVC + DC.
DC is a constant term and
is independent of Q.
Order Size (Q)
Annual Ordering
Cost
Annual
Inventory
Costs
Total Annual
Variable Cost
(TVC)
50
$120
$30
$150
75
$80
$45
$125
100
$60
$60
$120
125
$48
$75
$123
150
$40
$90
$130
175
$34
$105
$139
200
$30
$120
$150
225
$27
$135
$162
250
$24
$150
$174
275
$22
$165
$187
300
$20
$180
$200
17
Economic Production (EPQ)
Model
18
Economic Production Quantity
The economic production quantity (EPQ) model is used in
manufacturing situations where inventory is replenished at a
finite rate given by the production rate of the item under
consideration.
We define two more variables:
p: Production rate per day (daily production)
d: Demand rate per day (daily demand)
Note: p and d must be defined in the same time unit. For example
these could be weekly instead of daily rates.
19
Economic Production Quantity continued
Suppose
p = 50 units/day
d = 10 units/day
EPQ = 500 (production quantity, Q); Note: the optimal value of
Q is EPQ or QP
In this case we will need 10 days to produce 500 units
(EPQ/p = 500/50).
20
Economic Production Quantity continued
During these ten days, we produce 50 units per day but also use
10 units per day.
Therefore, we are building up inventory at the rate of 40 (p-d
=50-10) units per day.
At the end of 10 days, the total number of units in inventory is
400 (40 * 10). This is the maximum inventory level, Imax.
After 50 days, the next batch consisting of EPQ units is
scheduled for production. This is how the cycles continue.
21
Economic Production Quantity continued
At the end of the 10th day, we stop producing this item and then
continue to meet the demand from the inventory. The inventory
will last for 40 days (400/10) because we have 400 units in stock
and the demand rate is 10 units/day.
The production cycle thus consists of 50 days. For the first 10
days we produce and use the item. For the next 40 days, there is
no production and there is only the usage of the item.
22
Economic Production Quantity continued
The maximum inventory level as explained
earlier is Imax = Q (1- d/p) = 400.
Average Inventory = (Imax)/2
Annual Setup Cost = (D/Q)S
Annual Holding Cost = H  I 2
m ax
TVC 

 Q  d 
  H  1  
p

 2 
D
 Q  d 
S  H  1  
Q
p
 2 
EPQ is obtained by equating the annual setup
cost with annual holding cost and then solving for
Q. The expression for EPQ is given on the RHS.
EPQ 
2 DS

d

H
1



p


23
Example: EPQ
Annual Demand (D) = 50,000 units, Setup Cost (S) =$25.00 per
set up, Inventory Holding Cost (H) = $5.00 per unit per year.
Production rate (p) = 500 units per day.
Number of working days = 250. Demand occurs only during the
working days. Therefore, (d) = 50,000/250 = 200.
EPQ (QP) = 912.87 =
Imax = 548.
24
Quantity (Price) Discount
Model
25
Quantity (Price) Discount Model
Quantity discount model is used when the vendor (supplier)
offers a discount for buying in large quantities.
For example, the supplier may quote a price of $ 10.00 per unit
for order size 1 to 999 and $ 9.50 for order size of 1,000 or more.
This scenario is also called a “price break” at quantity 1,000.
There could be several price breaks.
26
Example: Quantity (Price) Discounts
The annual demand (D) for an item is 240,000 units. The ordering cost per order (S) is
$ 30.00. The inventory carrying cost per unit per year (H) is 30% of the cost (price) of
the item, that is, H = 30% of C.
The vendor has quoted the following costs (prices).
Price 1: $ 2.80 for order quantity less than or equal to 29,999.
Price 2: $ 2.77 for order quantity 30,000 and above.
Find the Economic Order quantity.
27
Example: Quantity (Price) Discounts
(continued)
To solve this problem we will compare the total costs for both
prices. As in the EOQ model, the economic order quantity is
given by the following equation,
QO =
and, the total cost (TC) is given by the following equation:
TC = (D/Q)*S + (Q/2)*H + D*C
28
Example: Quantity (Price) Discounts
(continued)
Start calculations by finding EOQ at the lower price ($ 2.77).
The inventory carrying cost for this price is $0.83 (= 30% of $ 2.77) per unit
per year and the economic order quantity for this price is 4,163.
However, we cannot buy 4,163 units at the price of $ 2.77 because the
minimum quantity specified by the vendor at this price is 30,000.
Therefore, we have to buy at least 30,000 units to obtain this price discount.
We calculate the total cost TC (at 30,000). Using the TC equation,
TC (at 30,000) = (240,000/30,000)*30 + (30,000/2)*0.83 + 240,000*2.77 = $ 677,505.00
29
Example: Quantity (Price) Discounts
(continued)
Now calculate the EOQ for the higher price $ 2.80.
The value of H for this price is $ 0.84 (30% of $ 2.80).
The economic order quantity is 4,140.
This quantity is feasible because we can by up to 29,999 units at $ 2.80 per
unit.
The total cost, TC(at 4,140) will be:
TC (at 4,140) = = (240,000/4,140)*30 + (4,140/2)*0.84 + 240,000*2.80 = $ 675,477.93.
The order quantity for this example is 4,140
since TC (at 4,140) < TC (at 30,000).
30
ABC Analysis
31
ABC Analysis
Some materials are more important than others.
Importance can be established in the following two
ways:
o
Material Criticality
o
Annual Dollar Volume of Materials
32
Material Criticality
There are various definitions of ‘‘critical’’ that fit different
situations. For example, a part is critical when:
o
A part failure causes product or process failure.
o
Part failure can have a probability (not a certainty) of stopping
the process or product.
o
Part failure reduces production output by a significant amount.
o
Danger involved in using materials. Flammability,
explosiveness, and toxicity of fumes are crucial safety factors
for materials management.
33
Material Criticality (continued)
Whichever definition of criticality is used, the procedure is to list first the
most critical parts.
Next, systematically rank-order parts according to their relative criticality.
The concept of criticality should reflect the costs of failures, including safety
dangers, loss of life, and losses in production output.
Curves similar to the figure on RHS
can be created for such situations.
34
Annual Dollar Volume of Materials
ABC categories are based on sorting materials by their annual dollar volume.
Dollar volume is the surrogate for potential savings that can be made by
improving the inventory management of specific materials.
Accordingly, all parts, components, and other materials used by a company
should be listed and then rank ordered by their annual dollar volume.
Start with those items that have the highest levels of dollar volume and rank
order them from the highest to the lowest levels.
o
The top 25 percent of these materials are called A-type items.
o
The next 25 percent are called B-type items.
o
The bottom 50 percent are called C-type items.
35
Annual Dollar Volume of Materials
(continued)
However, there is no fixed convention that A, B, and C class breaks must
occur at 25 and 50 percent.
Companies differ with respect to what percent of all items stocked account for
75 percent of their total annual dollar volume.
The figure on RHS portrays a typical
case where 20 to 30 percent of all
items carried account for as much as
70 to 80 percent of the company’s
total dollar volume.
36
Annual Dollar Volume of Materials Example
Unit Cost
Annual Dollar
Volume
Percentage of
Annual Dollar
Volume
Cumulative % of
Annual Dollar
Volume
Percentage
of Number
of Items
Stocked
Cumulative % of
Number of Items
Stocked
Category
1250
$92.00
$115,000.00
40.17%
40.17%
10.00%
10.00%
A
Q
530
$168.00
$89,040.00
31.10%
71.26%
10.00%
20.00%
A
R
1970
$18.75
$36,937.50
12.90%
84.17%
10.00%
30.00%
B
S
430
$42.20
$18,146.00
6.34%
90.50%
10.00%
40.00%
B
T
990
$13.80
$13,662.00
4.77%
95.27%
10.00%
50.00%
B
U
680
$12.50
$8,500.00
2.97%
98.24%
10.00%
60.00%
C
V
2150
$0.98
$2,107.00
0.74%
98.98%
10.00%
70.00%
C
W
210
$9.80
$2,058.00
0.72%
99.70%
10.00%
80.00%
C
X
1250
$0.52
$650.00
0.23%
99.93%
10.00%
90.00%
C
Y
335
$0.64
$214.40
0.07%
100.00%
10.00%
100.00%
C
Total
$286,314.90
Item Stock
Number
Annual
Volume
(Units)
P
37
Lead-Times
Lead time (LT) is the interval that elapses between the recognition that an
order should be placed and the delivery of that order. See Figure below.
The diminishing stock level reaches a threshold (or limen) called QRP - the
stock level of the reorder point.
The threshold triggers the order for replenishment.
The stock level at the reorder point, RP, is enough to meet orders until the
replenishment supply arrives and is ready to be used.
38
Lead-Times (continued)
Eight lead-time (LT) considerations that apply to EOQ or EPQ or
both:




The amount of time required to recognize the need to reorder.
The interval for doing whatever clerical work is needed to
prepare the order.
Mail, e-mail, EDI, or telephone intervals to communicate with
the supplier (or suppliers) and to place the order(s).
Time that takes the supplier’s organization to react to the
placement of an order?
39
Lead-Times (continued)




Delivery time including loading, transit, and unloading.
Processing of delivered items by the receiving department.
Inspection to be sure items match specifications.
Time delays in updating records The effect of such delays on
the production schedule must be considered.
The eight lead-time components are added to get the lead time.
Lead times are usually variable.
Safety stocks may be increased to deal with variable lead times.
40
Order Point Policies (OPP)
Order point policies (OPP) define the stock level at which an
order will be placed. The reorder point (RP), triggers an order for
more stock.
OPP systems specify the number of units to order and when to
order.
We will discuss the following two systems


Periodic, also known as fixed time, inventory systems.
Perpetual, also known as fixed quantity, inventory systems.
41
Periodic (Fixed Time) Inventory
Systems
The interval between orders is fixed while the ordered amount varies.
The order size is determined by the amount of stock on-hand when the record
is read.
It is the date that triggers the review and the order being placed.
See the figure on RHS.
42
Perpetual (Fixed Quantity) Inventory
Systems
Perpetual, also known as fixed quantity, inventory systems continuously
record inventory received from suppliers and withdrawn by employees.
An order is placed when reorder point is reached.
The amount ordered is same (generally EOQ or EPQ) in each cycle.
The interval between placing orders is different in each cycle because of
demand variability.
See the figure on RHS.
43
Reorder Point and Safety (Buffer) Stock
Shortages occur whenever actual demand in the lead-time period exceeds QRP.
The likelihood of a shortage will be decreased by increasing the value of
safety( buffer) stock.
Determining safety (buffer) stock level requires an economic balancing
situation between the cost of going out of stock versus the cost of carrying
more inventory.
The large buffer stock means that the carrying cost of stock is high to make
sure that the actual cost of stock-outages is small.
The stock level of the reorder point (QRP) is equal to the expected (average)
demand during the lead time period plus the safety stock (SS) quantity.
Thus,
QRP =
LT
+ SS
44
Expected Demand During Lead Time
The expected demand during lead time is a function of average demand per
day (d) and the magnitude of lead time (LT) and is determined as
It may be noted that calculation of demand during lead time becomes complex
if lead time also varies.
45
Safety Stock Calculations
The value of SS depends on the variability of demand and the service level.
The service level is a measure of the stock-out situations allowed. For
example, a 95% service level means that there will be no out-of-stock situation
95% of the time during lead time.
Assuming that the demand follows a normal distribution the value of SS can be
determined as
SS = zσLT
where, σLT is the standard deviation of demand during lead time and z is a
measure of the service level that we want to provide. z is called standard
normal random variable and can be found from its statistical table. For the
95% service level the value of z = 1.65.
46
Two-Bin Perpetual Invenory Control
System
The two-bin system is a smart way of continuously monitoring
the order point.
It is a simple self-operating perpetual inventory system.
See the figure below.
47
Thank you
48