Forecasting using simple models - PowerPoint PPT Presentation

1 / 144
About This Presentation
Title:

Forecasting using simple models

Description:

Forecasting using simple models Outline Basic forecasting models The basic ideas behind each model When each model may be appropriate Illustrate with examples ... – PowerPoint PPT presentation

Number of Views:395
Avg rating:3.0/5.0
Slides: 145
Provided by: Dana85
Category:

less

Transcript and Presenter's Notes

Title: Forecasting using simple models


1
Forecasting using simple models
2
Outline
  • Basic forecasting models
  • The basic ideas behind each model
  • When each model may be appropriate
  • Illustrate with examples
  • Forecast error measures
  • Automatic model selection
  • Adaptive smoothing methods
  • (automatic alpha adaptation)
  • Ideas in model based forecasting techniques
  • Regression
  • Autocorrelation
  • Prediction intervals

3
Basic Forecasting Models
  • Moving average and weighted moving average
  • First order exponential smoothing
  • Second order exponential smoothing
  • First order exponential smoothing with trends
    and/or seasonal patterns
  • Crostons method

4
M-Period Moving Average
  • i.e. the average of the last M data points
  • Basically assumes a stable (trend free) series
  • How should we choose M?
  • Advantages of large M?
  • Advantages of large M?
  • Average age of data M/2

5
Weighted Moving Averages
  • The Wi are weights attached to each historical
    data point
  • Essentially all known (univariate) forecasting
    schemes are weighted moving averages
  • Thus, dont screw around with the general
    versions unless you are an expert

6
Simple Exponential Smoothing
  • Pt1(t) Forecast for time t1 made at time t
  • Vt Actual outcome at time t
  • 0lt?lt1 is the smoothing parameter

7
Two Views of Same Equation
  • Pt1(t) Pt(t-1) ?Vt Pt(t-1)
  • Adjust forecast based on last forecast error
  • OR
  • Pt1(t) (1- ?)Pt(t-1) ?Vt
  • Weighted average of last forecast and last Actual

8
Simple Exponential Smoothing
  • Is appropriate when the underlying time series
    behaves like a constant Noise
  • Xt ? Nt
  • Or when the mean ? is wandering around
  • That is, for a quite stable process
  • Not appropriate when trends or seasonality present

9
ES would work well here
10
Simple Exponential Smoothing
  • We can show by recursive substitution that ES can
    also be written as
  • Pt1(t) ?Vt ?(1-?)Vt-1 ?(1-?)2Vt-2
    ?(1-?)3Vt-3 ..
  • Is a weighted average of past observations
  • Weights decay geometrically as we go backwards in
    time

11
(No Transcript)
12
Simple Exponential Smoothing
  • Ft1(t) ?At ?(1-?)At-1 ?(1-?)2At-2
    ?(1-?)3At-3 ..
  • Large ? adjusts more quickly to changes
  • Smaller ? provides more averaging and thus
    lower variance when things are stable
  • Exponential smoothing is intuitively more
    appealing than moving averages

13
Exponential Smoothing Examples
14
Zero Mean White Noise
15
(No Transcript)
16
(No Transcript)
17
Shifting Mean Zero Mean White Noise
18
(No Transcript)
19
(No Transcript)
20
Automatic selection of ?
  • Using historical data
  • Apply a range of ? values
  • For each, calculate the error in one-step-ahead
    forecasts
  • e.g. the root mean squared error (RMSE)
  • Select the ? that minimizes RMSE

21
RMSE vs Alpha
1.45
1.4
1.35
RMSE
1.3
1.25
1.2
1.15
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Alpha
22
Recommended Alpha
  • Typically alpha should be in the range 0.05 to
    0.3
  • If RMSE analysis indicates larger alpha,
    exponential smoothing may not be appropriate

23
(No Transcript)
24
(No Transcript)
25
Might look good, but is it?
26
(No Transcript)
27
(No Transcript)
28
Series and Forecast using Alpha0.9
2
1.5
1
Forecast
0.5
0
-0.5
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
Period
29
Forecast RMSE vs Alpha
0.67
0.66
0.65
0.64
0.63
Forecast RMSE
0.62
Series1
0.61
0.6
0.59
0.58
0.57
0
0.2
0.4
0.6
0.8
1
Alpha
30
(No Transcript)
31
(No Transcript)
32
Forecast RMSE vs Alpha
for Lake Huron Data
1.1
1.05
1
0.95
0.9
RMSE
0.85
0.8
0.75
0.7
0.65
0.6
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Alpha
33
(No Transcript)
34
(No Transcript)
35
Forecast RMSE vs Alpha
for Monthly Furniture Demand Data
45.6
40.6
35.6
30.6
25.6
RMSE
20.6
15.6
10.6
5.6
0.6
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Alpha
36
Exponential smoothing will lag behind a trend
  • Suppose Xtb0 b1t
  • And St (1- ?)St-1 ?Xt
  • Can show that

37
(No Transcript)
38
Double Exponential Smoothing
  • Modifies exponential smoothing for following a
    linear trend
  • i.e. Smooth the smoothed value

39
St Lags
St2 Lags even more
40
2St -St2 doesnt lag
41
(No Transcript)
42
(No Transcript)
43
(No Transcript)
44
Example
45
?0.2
46
Single Lags a trend
47
6
5
4
Double Over-shoots a change (must re-learn the
slope)
3
Trend
2
Series Data
Single Smoothing
Double smoothing
1
0
-1
1
6
11
16
21
26
31
36
41
46
51
56
61
66
71
76
81
86
91
96
101
48
Holt-Winters Trend and Seasonal Methods
  • Exponential smoothing for data with trend and/or
    seasonality
  • Two models, Multiplicative and Additive
  • Models contain estimates of trend and seasonal
    components
  • Models smooth, i.e. place greater weight on
    more recent data

49
Winters Multiplicative Model
  • Xt (b1b2t)ct ?t
  • Where ct are seasonal terms and
  • Note that the amplitude depends on the level of
    the series
  • Once we start smoothing, the seasonal components
    may not add to L

50
Holt-Winters Trend Model
  • Xt (b1b2t) ?t
  • Same except no seasonal effect
  • Works the same as the trend season model except
    simpler

51
  • Example

52
(10.04t)
53
150
54
50
55
  • The seasonal terms average 100 (i.e. 1)
  • Thus summed over a season, the ct must add to L
  • Each period we go up or down some percentage of
    the current level value
  • The amplitude increasing with level seems to
    occur frequently in practice

56
Recall Australian Red Wine Sales
57
Smoothing
  • In Winters model, we smooth the permanent
    component, the trend component and the
    seasonal component
  • We may have a different smoothing parameter for
    each (?, ?, ?)
  • Think of the permanent component as the current
    level of the series (without trend)

58
(No Transcript)
59
Current Observation
60
Current Observation deseasonalized
61
Estimate of permanent component from last time
last level slope1
62
(No Transcript)
63
(No Transcript)
64
observed slope
65
observed slope
previous slope
66
(No Transcript)
67
(No Transcript)
68
Extend the trend out ? periods ahead
69
Use the proper seasonal adjustment
70
Winters Additive Method
  • Xt b1 b2t ct ?t
  • Where ct are seasonal terms and
  • Similar to previous model except we smooth
    estimates of b1, b2, and the ct

71
Crostons Method
  • Can be useful for intermittent, erratic, or
    slow-moving demand
  • e.g. when demand is zero most of the time (say
    2/3 of the time)
  • Might be caused by
  • Short forecasting intervals (e.g. daily)
  • A handful of customers that order periodically
  • Aggregation of demand elsewhere (e.g. reorder
    points)

72
(No Transcript)
73
Typical situation
  • Central spare parts inventory (e.g. military)
  • Orders from manufacturer
  • in batches (e.g. EOQ)
  • periodically when inventory nearly depleted
  • long lead times may also effect batch size

74
Example
Demand each period follows a distribution that
is usually zero
75
Example
76
Example
  • Exponential smoothing applied (?0.2)

77
Using Exponential Smoothing
  • Forecast is highest right after a non-zero demand
    occurs
  • Forecast is lowest right before a non-zero demand
    occurs

78
Crostons Method
  • Separately Tracks
  • Time between (non-zero) demands
  • Demand size when not zero
  • Smoothes both time between and demand size
  • Combines both for forecasting

Demand Size Forecast
Time between demands
79
Define terms
  • V(t) actual demand outcome at time t
  • P(t) Predicted demand at time t
  • Z(t) Estimate of demand size (when it is not
    zero)
  • X(t) Estimate of time between (non-zero)
    demands
  • q a variable used to count number of
    periods between non-zero demand

80
Forecast Update
  • For a period with zero demand
  • Z(t)Z(t-1)
  • X(t)X(t-1)
  • No new information about
  • order size Z(t)
  • time between orders X(t)
  • qq1
  • Keep counting time since last order

81
Forecast Update
  • For a period with non-zero demand
  • Z(t)Z(t-1) ?(V(t)-Z(t-1))
  • X(t)X(t-1) ?(q - X(t-1))
  • q1

82
Forecast Update
  • For a period with non-zero demand
  • Z(t)Z(t-1) ?(V(t)-Z(t-1))
  • X(t)X(t-1) ?(q - X(t-1))
  • q1
  • Update Size of order via smoothing

Latest order size
83
Forecast Update
  • For a period with non-zero demand
  • Z(t)Z(t-1) ?(V(t)-Z(t-1))
  • X(t)X(t-1) ?(q - X(t-1))
  • q1
  • Update size of order via smoothing
  • Update time between orders via smoothing

Latest time between orders
84
Forecast Update
  • For a period with non-zero demand
  • Z(t)Z(t-1) ?(V(t)-Z(t-1))
  • X(t)X(t-1) ?(q - X(t-1))
  • q1
  • Update size of order via smoothing
  • Update time between orders via smoothing
  • Reset counter of time between orders

Reset counter
85
Forecast
  • Finally, our forecast is

86
Recall example
  • Exponential smoothing applied (?0.2)

87
Recall example
  • Crostons method applied (?0.2)

88
What is it forecasting?
  • Average demand per period

True average demand per period0.176
89
Behavior
  • Forecast only changes after a demand
  • Forecast constant between demands
  • Forecast increases when we observe
  • A large demand
  • A short time between demands
  • Forecast decreases when we observe
  • A small demand
  • A long time between demands

90
Crostons Method
  • Crostons method assumes demand is independent
    between periods
  • That is one period looks like the rest
  • (or changes slowly)

91
Counter Example
  • One large customer
  • Orders using a reorder point
  • The longer we go without an order
  • The greater the chances of receiving an order
  • In this case we would want the forecast to
    increase between orders
  • Crostons method may not work too well

92
Better Examples
  • Demand is a function of intermittent random
    events
  • Military spare parts depleted as a result of
    military actions
  • Umbrella stocks depleted as a function of rain
  • Demand depending on start of construction of
    large structure

93
Is demand Independent?
  • If enough data exists we can check the
    distribution of time between demand
  • Should tail off geometrically

94
Theoretical behavior
95
In our example
96
Comparison
97
Counterexample
  • Crostons method might not be appropriate if the
    time between demands distribution looks like this

98
Counterexample
  • In this case, as time approaches 20 periods
    without demand, we know demand is coming soon.
  • Our forecast should increase in this case

99
Error Measures
  • Errors The difference between actual and
    predicted (one period earlier)
  • et Vt Pt(t-1)
  • et can be positive or negative
  • Absolute error et
  • Always positive
  • Squared Error et2
  • Always positive
  • The percentage error PEt 100et / Vt
  • Can be positive or negative

100
Bias and error magnitude
  • Forecasts can be
  • Consistently too high or too low (bias)
  • Right on average, but with large deviations both
    positive and negative (error magnitude)
  • Should monitor both for changes

101
Error Measures
  • Look at errors over time
  • Cumulative measures summed or averaged over all
    data
  • Error Total (ET)
  • Mean Percentage Error (MPE)
  • Mean Absolute Percentage Error (MAPE)
  • Mean Squared Error (MSE)
  • Root Mean Squared Error (RMSE)
  • Smoothed measures reflects errors in the recent
    past
  • Mean Absolute Deviation (MAD)

102
Error Measures
Measure Bias
  • Look at errors over time
  • Cumulative measures summed or averaged over all
    data
  • Error Total (ET)
  • Mean Percentage Error (MPE)
  • Mean Absolute Percentage Error (MAPE)
  • Mean Squared Error (MSE)
  • Root Mean Squared Error (RMSE)
  • Smoothed measures reflects errors in the recent
    past
  • Mean Absolute Deviation (MAD)

103
Error Measures
Measure error magnitude
  • Look at errors over time
  • Cumulative measures summed or averaged over all
    data
  • Error Total (ET)
  • Mean Percentage Error (MPE)
  • Mean Absolute Percentage Error (MAPE)
  • Mean Squared Error (MSE)
  • Root Mean Squared Error (RMSE)
  • Smoothed measures reflects errors in the recent
    past
  • Mean Absolute Deviation (MAD)

104
Error Total
  • Sum of all errors
  • Uses raw (positive or negative) errors
  • ET can be positive or negative
  • Measures bias in the forecast
  • Should stay close to zero as we saw in last
    presentation

105
MPE
  • Average of percent errors
  • Can be positive or negative
  • Measures bias, should stay close to zero

106
MSE
  • Average of squared errors
  • Always positive
  • Measures magnitude of errors
  • Units are demand units squared

107
RMSE
  • Square root of MSE
  • Always positive
  • Measures magnitude of errors
  • Units are demand units
  • Standard deviation of forecast errors

108
MAPE
  • Average of absolute percentage errors
  • Always positive
  • Measures magnitude of errors
  • Units are percentage

109
Mean Absolute Deviation
  • Smoothed absolute errors
  • Always positive
  • Measures magnitude of errors
  • Looks at the recent past

110
Percentage or Actual units
  • Often errors naturally increase as the level of
    the series increases
  • Natural, thus no reason for alarm
  • If true, percentage based measured preferred
  • Actual units are more intuitive

111
Squared or Absolute Errors
  • Absolute errors are more intuitive
  • Standard deviation units less so
  • 66 within ? 1 S.D.
  • 95 within ? 2 S.D.
  • When using measures for automatic model
    selection, there are statistical reasons for
    preferring measures based on squared errors

112
Ex-Post Forecast Errors
  • Given
  • A forecasting method
  • Historical data
  • Calculate (some) error measure using the
    historical data
  • Some data required to initialize forecasting
    method.
  • Rest of data (if enough) used to calculate
    ex-post forecast errors and measure

113
Automatic Model Selection
  • For all possible forecasting methods
  • (and possibly for all parameter values e.g.
    smoothing constants but not in SAP?)
  • Compute ex-post forecast error measure
  • Select method with smallest error

114
Automatic ? Adaptation
  • Suppose an error measure indicates behavior has
    changed
  • e.g. level has jumped up
  • Slope of trend has changed
  • We would want to base forecasts on more recent
    data
  • Thus we would want a larger ?

115
Tracking Signal (TS)
  • Bias/Magnitude Standardized bias

116
? Adaptation
  • If TS increases, bias is increasing, thus
    increase ?
  • I dont like these methods due to instability

117
Model Based Methods
  • Find and exploit patterns in the data
  • Trend and Seasonal Decomposition
  • Time based regression
  • Time Series Methods (e.g. ARIMA Models)
  • Multiple Regression using leading indicators
  • Assumes series behavior stays the same
  • Requires analysis (no automatic model
    generation)

118
Univariate Time Series Models Based on
Decomposition
  • Vt the time series to forecast
  • Vt Tt St Nt
  • Where
  • Tt is a deterministic trend component
  • St is a deterministic seasonal/periodic component
  • Nt is a random noise component

119
?(Vt)0.257
120
(No Transcript)
121
Simple Linear Regression Model
Vt2.8771740.020726t
122
Use Model to Forecast into the Future
123
Residuals Actual-Predictedet
Vt-(2.8771740.020726t)
?(et)0.211
124
Simple Seasonal Model
  • Estimate a seasonal adjustment factor for each
    period within the season
  • e.g. SSeptember

125
Sorted by season
Season averages
126
Trend Seasonal Model
  • Vt2.8771740.020726t Smod(t,3)
  • Where
  • S1 0.250726055
  • S2 -0.242500035
  • S3 -0.008226125

127
(No Transcript)
128
e?t Vt - (2.877174 0.020726t Smod(t,3))
?(e?t)0.145
129
Can use other trend models
  • Vt ?0 ?1Sin(2?t/k) (where k is period)
  • Vt ?0 ?1t ?2t2 (multiple regression)
  • Vt ?0 ?1ekt
  • etc.
  • Examine the plot, pick a reasonable model
  • Test model fit, revise if necessary

130
(No Transcript)
131
(No Transcript)
132
Model Vt Tt St Nt
  • After extracting trend and seasonal components we
    are left with the Noise
  • Nt Vt (Tt St)
  • Can we extract any more predictable behavior from
    the noise?
  • Use Time Series analysis
  • Akin to signal processing in EE

133
Zero Mean, and AperiodicIs our best forecast
?
134
AR(1) Model
  • This data was generated using the model
  • Nt 0.9Nt-1 Zt
  • Where Zt N(0,?2)
  • Thus to forecast Nt1,we could use

135
(No Transcript)
136
(No Transcript)
137
Time Series Models
  • Examine the correlation of the time series to
    past values.
  • This is called autocorrelation
  • If Nt is correlated to Nt-1, Nt-2,..
  • Then we can forecast better than

138
Sample Autocorrelation Function
139
Back to our Demand Data
140
No Apparent Significant Autocorrelation
141
Multiple Linear Regression
  • V ?0 ?1 X1 ?2 X2 . ?p Xp ?
  • Where
  • V is the independent variable you want to
    predict
  • The Xis are the dependent variables you want to
    use for prediction (known)
  • Model is linear in the ?is

142
Examples of MLR in Forecasting
  • Vt ?0 ?1t ?2t2 ?3Sin(2?t/k) ?4ekt
  • i.e a trend model, a function of t
  • Vt ?0 ?1X1t ?2X2t
  • Where X1t and X2t are leading indicators
  • Vt ?0 ?1Vt-1 ?2Vt-2 ?12Vt-12 ?13Vt-13
  • An Autoregressive model

143
Example Sales and Leading Indicator
144
Example Sales and Leading Indicator
Sales(t) -3.930.83Sales(t-3)
-0.78Sales(t-2)1.22Sales(t-1) -5.0Lead(t)
Write a Comment
User Comments (0)
About PowerShow.com