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Forecasting using simple models

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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

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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
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Shifting Mean Zero Mean White Noise
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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

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Might look good, but is it?
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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
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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
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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

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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
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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)

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Current Observation
60
Current Observation deseasonalized
61
Estimate of permanent component from last time
last level slope1
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64
observed slope
65
observed slope
previous slope
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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)

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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
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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

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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

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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

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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)
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