1. BUAD306
Chapter 3 – Forecasting

2. Everyday Forecasting
Weather
Time
Traffic
Other examples???

3. Forecasting What is forecasting? How is it used in business?
Approaches to forecasting
Forecasting techniques

4. What is Forecasting? Forecast: A statement about the future
Used to help managers:
Plan the system
Plan the use of the system

5. Use of Forecasts Accounting Cost/profit estimates Finance
Cash flow and funding
Human Resources
Hiring/recruiting/training
Marketing
Pricing, promotion, strategy
MIS
IT/IS systems, services
Operations
Schedules, MRP, workloads
Product/service design
New products and services

6. Forecasting Basics Assumes causal system past ==> future
Forecasts rarely perfect because of randomness
Forecasts more accurate for groups vs. individuals
Forecast accuracy decreases as time horizon increases

7. Elements of a Good Forecast
Timely – feasible horizon
Reliable – works consistently
Accurate – degree should be stated
Expressed in meaningful units
Written – for consistency of usage
Easy to Use - KISS

8. Approaches to Forecasting
Judgmental – subjective inputs
Time Series – historical data
Associative – explanatory variables

9. Judgmental Forecasts Executive Opinions  Accuracy??
Sales Force Feedback  Bias???
Consumer Surveys
Outside Opinions Industry experts

10. What would you rather evaluate?
Period A B C 1 30 18 46 2 34 17 26 3 32 19 27 4 23 5 35 22 6 48 7 29 8 36 25 20 9 24 14 10 31 11 47 12 28 13 37 15 33 16

11. Time Series Forecasts Based on observations over a period of time
Identifies:
Trend – LT movement in data
Seasonality – ST variations
Cycles – wavelike variations
Irregular Variations – unusual events
Random Variations – chance/residual
Examples on the board

12. Forecast Variations Trend Cycles Irregular variation 90 89 88
Seasonal Variations 90 89 88
Cycles

13. Examples on the board & HW#1…
Naïve Forecasting
Simple to use
Minimal to no cost
Data analysis is almost nonexistent
Easily understandable
Cannot provide high accuracy
Can be a standard for accuracy
Examples on the board & HW#1…

14. HW Problem 1 Day Muffins Buns Cupcakes 1 30 18 46 2 34 17 26 3 32 1927 4 23 5 35 22 6 48 7 29 8 36 25 20 9 24 14 10 31 11 47 12 28 13 37 15 33 16

15. HW Problem 1
Muffins
Buns
Cupcakes

16. Techniques for Averaging
Moving average
Weighted moving average
Exponential smoothing

17. Simple Moving Average MAn = n Ai  Where:
i = index that corresponds to periods
n = number of periods (data points)
Ai = Actual value in time period I
MA = Moving Average
Ft = Forecast for period t

18. Example 1: Moving Average
Four period moving average for period 7:
Four period moving average for period 8:
Four period moving average for period 9 if actual for 8 = 5025:
Period
Sales 1
3520 2
2860 3
4005 4
3740 5
4310 6
5001 7
4890 8 ??

19. Weighted Moving Average
Similar to a moving average, but assigns more weight to the most recent observations.
Total of weights must equal 1.

20. Example 2: Weighted Moving Average
Period
Sales 1
3520 2
2860 3
4005 4
3740 5
4310 6
5001 7
4890 8 ??
Compute a weighted moving average forecast for period 8 using the following weights: .40, .30, .20 and .10:

21. HW #2 – Let’s Discuss Month Sales Feb 19 Mar 18 Apr 15 May 20 June
July 22
Aug

22. Calculating Error et = At - Ft Mathematically:
Let’s discuss examples on board…

23. Exponential Smoothing
Premise--The most recent observations might have the highest predictive value….
Therefore, we should give more weight to the more recent time periods when forecasting.

24. Exponential Smoothing
Ft = Ft-1 + (At-1 - Ft-1)
Next forecast =
Previous forecast +  (Actual -Previous Forecast)
Smoothing Constant

25. About   = Smoothing constant selected by forecaster
It is a percentage of the forecast error
The closer the value is to zero, the slower the forecast will be to adjust to forecast errors (greater smoothing)
The higher the value is to 1.00, the greater the responsiveness to errors and the less smoothing
READ TEXT

26. Example 3: Exponential Smoothing
Ft = Ft-1 + (At-1 - Ft-1)
Assume a starting forecast of 4030 for period 3.
Given data at left and  = .10, what would the forecast be for period 8?
Period
Sales 1
3520 2
2860 3
4005 4
3740 5
4310 6
5001 7
4890 8 ??

27. Example 3: Exponential Smoothing
Period
Act
Forecast Calc
Fore 3
4005
4030 4
3740 5
4310 6
5001 7
4890 8

28. HW #2 – Let’s Discuss Month Sales Feb 19 Mar 18 Apr 15 May 20 June
July 22
Aug

29. Techniques for Seasonality
Seasonal Variations – regularly repeating movements in series values that can be tied to recurring events
Computing Seasonal Relatives: READ THE TEXT
Look at HW #12 – don’t have to know this for exam

30. Using Seasonal Relatives
Allows you to incorporate seasonality or deseasonalize data
Incorporate: Useful when trend and seasonality are apparent
Deseasonalize – Remove seasonal components to get a clearer picture of non-seasonal components

31. Example 4: Using Seasonal Relatives
A publisher wants to predict quarterly demand for a certain book for periods 9 and 16, which happen to be in the 3rd and 2nd quarters of a particular year. The data series consists of both trend and seasonality. The trend portion of demand is projected using the equation: yt=12, t.
Quarter relatives are Q1= 1.3, Q2=.8, Q3=1.4, Q4=.9
Use this information to predict demand for periods 9 and 16.
The trend values:
Applying the relatives:

32. HW #11 – Let’s Discuss Ft = 40 – 6.5t + 2t2
The following equation summarizes the trend portion of quarterly sales of condos over a long cycle. Prepare a forecast for each Q of 2014 and 1Q15.
Ft = 40 – 6.5t + 2t2
Ft = unit sales
t= 0 at 1Q 2012
Quarter
Relative 1
1.1 2 3 .6 4
1.3

33. Assoc. Forecasting Technique: Simple Linear Regression
Predictor variables - used to predict values of variable interest
Regression - technique for fitting a line to a set of points
Least squares line - minimizes sum of squared deviations around the line

34. Linear Regression Assumptions
Variations around line are random
No patterns are apparent
Deviations around the line should be normally distributed
Predictions are being made only in the range of observed values
Should use minimum of 20 observations for best results

35. Suppose you analyze the following data...

36. y c = a + bx b = n (xy) - (x)(y) a = y - bx n n(x2) - (x)2
The regression line has the following equation:
y c = a + bx
Where: y c = Predicted (dependent) variable
x = Predictor (independent) variable
b = slope of the line
a = Value of y c when x=0
b = n (xy) - (x)(y)
n(x2) - (x)2
a = y - bx n

37. Example 5 - Linear Regression:
Suppose that a manufacturing company made batches of a certain product. The accountant for the company wished to determine the cost of a batch of product given the following data:
Size of batch 20 30 40 50 70 80
100
120
150
Cost of batch (in 1000s)
$1.4
3.4
4.1
3.8
6.7
6.6
7.8
10.4
11.7
Question… which is
the dependent (y) and which is the independent (x) variable?

39. We are now ready to determine the values of b and a:
b = n (xy) - (x)(y) = 9 (5264) - (660)(55.9)
n(x2) - (x) (63600) - (660)2
= = =
a = y - bx = (660) =
n 9

40. y c = a + bx y c = y c = Our linear regression equation:
What is the cost of a batch of 125 pieces?
y c =

42. Problem #7 Freight car loadings at a busy port are as follows: Week #1
220 10
380 2
245 11
420 3
280 12
450 4
275 13
460 5
300 14
475 6
310 15
500 7
350 16
510 8
360 17
525 9
400 18
541
Freight car
loadings at a
busy port are as
follows:

43. Problem #7
b = n (xy) - (x)(y)
n(x2) - (x)2
a = y - bx n

44. Correlation (r) A measure of the relationship between two variables
Strength
Direction (positive or negative)
Ranges from to +1.00
Correlation close to 0 signifies a weak relationship – other variables may be at play
Correlation close to +1 or -1 signifies a strong relationship

45. Calculating a Correlation Coefficient
r = n( xy) - ( x)( y)
n( x2)- ( x)2 * n( y2) - ( y)2

46. r = 9 (5264) - (660)(55.9) 9(63600)- (660)2 * 9(439.11) - (55.9)2
Example 6: Continued
r = n( xy) - ( x)( y)
n( x2)- ( x)2 * n( y2) - ( y)2
r = (5264) - (660)(55.9)
9(63600)- (660)2 * 9(439.11) - (55.9)2
r = = =
* * 28.76

47. Coefficient of Determination (r2)
How well a regression line “fits” the data
Ranges from 0.00 to 1.00
The closer to 1.0, the better the fit

48. Example 6: Continued
r = .985
r2 = = .97

49. Conclusion of Example R = .985 R2 = .9852 = .97 Positive, close to one
Closer to one, the better the fit to the line

50. Forecast Accuracy
Error - difference between actual value and predicted value
Mean absolute deviation (MAD)
Average absolute error
Mean squared error (MSE)
Average of squared error
Why can’t we simply calculate error for each observed
period and then select the technique with the lowest error?

51. Does the # of errors calculated impact the "accuracy" comparison???
Error Example
Period
Actual
3PMA
5PMA
3P WMA .6, .3, .1
EX SM .2 LR 1 55
55.69 2 60
60.66 3 75 56
65.63 4 58
68.5
59.8
70.6 5 80
63.3
59.44
75.57 6 90 71
65.6
72.9
63.552
80.54 7 70 76
72.6
83.8
85.51 8 92
74.6 77
90.48 9
100 84 78
85.2
95.45 10
86.4
94.6
100.42
#errors?
Does the # of errors calculated impact the "accuracy" comparison???

52. Calculating Error et = At - Ft Mathematically:
What do the negative errors mean?
How do they affect total error?
et = At - Ft

53. Calculating MAD and MSE=
Actual
forecast   n
MSE =
Actual
forecast) - 1 2   n (

54. Conclusions with MAD & MSE
The MAD and MSE can be used as a comparison tool for several forecasting techniques.
The forecasting technique that yields the lowest MAD and MSE is the preferred forecasting method.

55. Which technique would you select for your forecast approach?
MAD & MSE Comparison
Tech
MAD
MSE
3 Period MA
3.6
8.1
Exp Sm .02
2.2
5.6
Exp Sm .04
2.6
6.1
Which technique would you select for your forecast approach?