Function to create (and/or modify) a c("regarima_spec","X13")
class object with the RegARIMA model specification
for the X13 method. The object can be created from a predefined 'JDemetra+' model specification (a character
),
a previous specification (c("regarima_spec","X13")
object) or a X13 RegARIMA model (c("regarima","X13")
).
regarima_spec_x13(
spec = c("RG5c", "RG0", "RG1", "RG2c", "RG3", "RG4c"),
preliminary.check = NA,
estimate.from = NA_character_,
estimate.to = NA_character_,
estimate.first = NA_integer_,
estimate.last = NA_integer_,
estimate.exclFirst = NA_integer_,
estimate.exclLast = NA_integer_,
estimate.tol = NA_integer_,
transform.function = c(NA, "Auto", "None", "Log"),
transform.adjust = c(NA, "None", "LeapYear", "LengthOfPeriod"),
transform.aicdiff = NA_integer_,
usrdef.outliersEnabled = NA,
usrdef.outliersType = NA,
usrdef.outliersDate = NA,
usrdef.outliersCoef = NA,
usrdef.varEnabled = NA,
usrdef.var = NA,
usrdef.varType = NA,
usrdef.varCoef = NA,
tradingdays.option = c(NA, "TradingDays", "WorkingDays", "UserDefined", "None"),
tradingdays.autoadjust = NA,
tradingdays.leapyear = c(NA, "LeapYear", "LengthOfPeriod", "None"),
tradingdays.stocktd = NA_integer_,
tradingdays.test = c(NA, "Remove", "Add", "None"),
easter.enabled = NA,
easter.julian = NA,
easter.duration = NA_integer_,
easter.test = c(NA, "Add", "Remove", "None"),
outlier.enabled = NA,
outlier.from = NA_character_,
outlier.to = NA_character_,
outlier.first = NA_integer_,
outlier.last = NA_integer_,
outlier.exclFirst = NA_integer_,
outlier.exclLast = NA_integer_,
outlier.ao = NA,
outlier.tc = NA,
outlier.ls = NA,
outlier.so = NA,
outlier.usedefcv = NA,
outlier.cv = NA_integer_,
outlier.method = c(NA, "AddOne", "AddAll"),
outlier.tcrate = NA_integer_,
automdl.enabled = NA,
automdl.acceptdefault = NA,
automdl.cancel = NA_integer_,
automdl.ub1 = NA_integer_,
automdl.ub2 = NA_integer_,
automdl.mixed = NA,
automdl.balanced = NA,
automdl.armalimit = NA_integer_,
automdl.reducecv = NA_integer_,
automdl.ljungboxlimit = NA_integer_,
automdl.ubfinal = NA_integer_,
arima.mu = NA,
arima.p = NA_integer_,
arima.d = NA_integer_,
arima.q = NA_integer_,
arima.bp = NA_integer_,
arima.bd = NA_integer_,
arima.bq = NA_integer_,
arima.coefEnabled = NA,
arima.coef = NA,
arima.coefType = NA,
fcst.horizon = NA_integer_
)
A list of class c("regarima_spec","X13")
with the following components, each referring to a different part
of the RegARIMA model specification, mirroring the arguments of the function (for details, see the arguments description).
Each lowest-level component (except span, pre-specified outliers, user-defined variables and pre-specified ARMA coefficients)
is structured within a data frame with columns denoting different variables of the model specification and rows referring to:
first row = base specification, as provided within the argument spec
;
second row = user modifications as specified by the remaining arguments of the function (e.g.: arima.d
);
and third row = final model specification, values that will be used in the function regarima
.
The final specification (third row) shall include user modifications (row two) unless they were wrongly specified.
The pre-specified outliers, user-defined variables and pre-specified ARMA coefficients consist of a list
of Predefined
(base model specification) and Final
values.
a data frame. Variables referring to: span
- time span for the model estimation, tolerance
- argument estimate.tol
. The final values can also be accessed with the function s_estimate
.
a data frame. Variables referring to: tfunction
- argument transform.function
, adjust
- argument transform.adjust
, aicdiff
- argument transform.aicdiff
. The final values can also be accessed with the function s_transform
.
a list containing the information on the user-defined variables (userdef
),
trading.days
effect and easter
effect. The user-defined part includes: specification
- data frame
with the information if pre-specified outliers (outlier
) and user-defined variables (variables
)
are included in the model and if fixed coefficients are used (outlier.coef
and variables.coef
).
The final values can also be accessed with the function s_usrdef
;
outliers
- matrices with the outliers (Predefined
and Final
).
The final outliers can also be accessed with the function s_preOut
; and variables
- a list with the Predefined
and Final
user-defined variables (series
) and its description
(description
) including the information on the variable type and the values of fixed coefficients.
The final user-defined variables can also be accessed with the function s_preVar
.
Within the data frame trading.days
, the variables refer to: option
- argument tradingdays.option, autoadjust
- argument tradingdays.autoadjust, leapyear
- argument tradingdays.leapyear, stocktd
- argument tradingdays.stocktd, test
- argument tradingdays.test
. The final trading.days
values can be also accessed with the function s_td
. Within the data frame easter
variables refer to: enabled
- argument easter.enabled, julian
- argument easter.julian, duration
- argument easter.duration, test
- argument easter.test
. The final easter
values can be also accessed with the function s_easter
.
a data frame. Variables referring to: enabled
- argument outlier.enabled
, span
- time span for the outlier detection, ao
- argument outlier.ao, tc
- argument outlier.tc, ls
- argument outlier.ls, so
- argument outlier.so, usedefcv
- argument outlier.usedefcv, cv
- argument outlier.cv, method
- argument outlier.method, tcrate
- argument outlier.tcrate
. The final values can also be accessed with the function s_out
.
a list of a data frame with the ARIMA settings (specification
) and matrices with the information
on the pre-specified ARMA coefficients (coefficients
). The matrix Predefined
refers to the pre-defined
model specification, and the matrix Final
to the final specification. Both matrices contain the value of the ARMA
coefficients and the procedure for its estimation.
In the data frame specification
, the variable enabled
refers to the argument automdl.enabled
and all remaining variables (automdl.acceptdefault, automdl.cancel, automdl.ub1, automdl.ub2, automdl.mixed,
automdl.balanced, automdl.armalimit, automdl.reducecv, automdl.ljungboxlimit, automdl.ubfinal, arima.mu, arima.p,
arima.d, arima.q, arima.bp, arima.bd, arima.bq
), to the respective function arguments.
The final values of the specification
can be also accessed with the function s_arima
and the final pre-specified ARMA coefficients, with the function s_arimaCoef
.
a data frame with the forecast horizon (argument fcst.horizon
).
The final value can also be accessed with the function s_fcst
.
a matrix containing the final time span for the model estimation and outlier detection.
It contains the same information as the variable span in the data frames estimate and outliers.
The matrix can be also accessed with the function s_span
.
the model specification. It can be the name (character
) of a pre-defined 'JDemetra+' model specification
(see Details), an object of class c("regarima_spec","X13")
or an object of class c("regarima", "X13")
.
The default value is "RG5c"
.
a Boolean to check the quality of the input series and exclude highly problematic ones (e.g. the series with a number of identical observations and/or missing values above pre-specified threshold values).
The time span of the series, which is the (sub)period used to estimate the regarima model, is controlled by the following six variables:
estimate.from, estimate.to, estimate.first, estimate.last, estimate.exclFirst
and estimate.exclLast
;
where estimate.from
and estimate.to
have priority over the remaining span control variables,
estimate.last
and estimate.first
have priority over estimate.exclFirst
and estimate.exclLast
,
and estimate.last
has priority over estimate.first
. Default= "All".
a character in format "YYYY-MM-DD" indicating the start of the time span (e.g. "1900-01-01").
It can be combined with the parameter estimate.to
.
a character in format "YYYY-MM-DD" indicating the end of the time span (e.g. "2020-12-31").
It can be combined with the parameter estimate.from
.
a numeric specifying the number of periods considered at the beginning of the series.
numeric specifying the number of periods considered at the end of the series.
a numeric specifying the number of periods excluded at the beginning of the series.
It can be combined with the parameter estimate.exclLast
.
a numeric specifying the number of periods excluded at the end of the series.
It can be combined with the parameter estimate.exclFirst
.
a numeric, convergence tolerance. The absolute changes in the log-likelihood function are compared to this value to check for the convergence of the estimation iterations.
the transformation of the input series: "None"
= no transformation of the series;
"Log"
= takes the log of the series; "Auto"
= the program tests for the log-level specification.
pre-adjustment of the input series for the length of period or leap year effects:
"None"
= no adjustment; "LeapYear"
= leap year effect; "LengthOfPeriod"
= length of period.
Modifications of this variable are taken into account only when transform.function
is set to "Log"
.
a numeric defining the difference in AICC needed to accept no transformation when the automatic
transformation selection is chosen (considered only when transform.function
is set to "Auto"
).
Control variables for the pre-specified outliers. The pre-specified outliers are used in the model only when enabled
(usrdef.outliersEnabled=TRUE
) and the outlier type (usrdef.outliersType
) and date
(usrdef.outliersDate
) are provided.
logical. If TRUE
, the program uses the pre-specified outliers.
a vector defining the outlier type. Possible types are: ("AO")
= additive,
("LS")
= level shift, ("TC")
= transitory change, ("SO")
= seasonal outlier.
E.g.: usrdef.outliersType = c("AO","AO","LS")
.
a vector defining the outlier dates. The dates should be characters in format "YYYY-MM-DD".
E.g.: usrdef.outliersDate= c("2009-10-01","2005-02-01","2003-04-01")
.
a vector providing fixed coefficients for the outliers. The coefficients can't be fixed if
transform.function
is set to "Auto"
i.e. the series transformation need to be pre-defined.
E.g.: usrdef.outliersCoef=c(200,170,20)
.
Control variables for the user-defined variables:
a logical. If TRUE
, the program uses the user-defined variables.
a time series (ts
) or a matrix of time series (mts
) with the user-defined variables.
a vector of character(s) defining the user-defined variables component type.
Possible types are: "Undefined", "Series", "Trend", "Seasonal", "SeasonallyAdjusted", "Irregular", "Calendar"
.
The type "Calendar"
must be used with tradingdays.option = "UserDefined"
to use user-defined calendar regressors.
If not specified, the program will assign the "Undefined"
type.
a vector providing fixed coefficients for the user-defined variables. The coefficients can't be fixed
if transform.function
is set to "Auto"
i.e. the series transformation need to be pre-defined.
to specify the set of trading days regression variables:
"TradingDays"
= six day-of-the-week regression variables;
"WorkingDays"
= one working/non-working day contrast variable;
"None"
= no correction for trading days and working days effects;
"UserDefined"
= user-defined trading days regressors (regressors must be defined by the usrdef.var
argument with usrdef.varType
set to "Calendar"
and usrdef.varEnabled = TRUE
).
"None"
must also be specified for the "day-of-week effects" correction (tradingdays.stocktd
to be modified accordingly).
a logical. If TRUE
, the program corrects automatically for the leap year effect.
Modifications of this variable are taken into account only when transform.function
is set to "Auto"
.
a character
to specify whether or not to include the leap-year effect in the model:
"LeapYear"
= leap year effect; "LengthOfPeriod"
= length of period, "None"
= no effect included.
The leap-year effect can be pre-specified in the model only if the input series hasn't been pre-adjusted
(transform.adjust
set to "None"
) and if the automatic correction for the leap-year effect isn't selected
(tradingdays.autoadjust
set to FALSE
).
a numeric indicating the day of the month when inventories and other stock are reported
(to denote the last day of the month, set the variable to 31). Modifications of this variable are taken into account
only when tradingdays.option
is set to "None"
.
defines the pre-tests for the significance of the trading day regression variables
based on the AICC statistics: "Add"
= the trading day variables are not included in the initial regression model
but can be added to the RegARIMA model after the test;
"Remove"
= the trading day variables belong to the initial regression model but can be removed from the RegARIMA model
after the test; "None"
= the trading day variables are not pre-tested and are included in the model.
a logical. If TRUE
, the program considers the Easter effect in the model.
a logical. If TRUE
, the program uses the Julian Easter (expressed in Gregorian calendar).
a numeric indicating the duration of the Easter effect (length in days, between 1 and 20).
defines the pre-tests for the significance of the Easter effect based on the t-statistic
(the Easter effect is considered as significant if the t-statistic is greater than 1.96):
"Add"
= the Easter effect variable is not included in the initial regression model but can be added
to the RegARIMA model after the test;
"Remove"
= the Easter effect variable belongs to the initial regression model but can be removed
from the RegARIMA model after the test;
"None"
= the Easter effect variable is not pre-tested and is included in the model.
a logical. If TRUE
, the automatic detection of outliers is enabled in the defined time span.
The time span during which outliers will be searched is controlled by the following
six variables: outlier.from, outlier.to, outlier.first, outlier.last, outlier.exclFirst
and outlier.exclLast
;
where outlier.from
and outlier.to
have priority over the remaining span control variables,
outlier.last
and outlier.first
have priority over outlier.exclFirst
and outlier.exclLast
,
and outlier.last
has priority over outlier.first
.
a character in format "YYYY-MM-DD" indicating the start of the time span (e.g. "1900-01-01").
It can be combined with the parameter outlier.to
.
a character in format "YYYY-MM-DD" indicating the end of the time span (e.g. "2020-12-31").
it can be combined with the parameter outlier.from
.
a numeric specifying the number of periods considered at the beginning of the series.
a numeric specifying the number of periods considered at the end of the series.
a numeric specifying the number of periods excluded at the beginning of the series.
It can be combined with the parameter outlier.exclLast
.
a numeric specifying the number of periods excluded at the end of the series.
It can be combined with the parameter outlier.exclFirst
.
a logical. If TRUE
, the automatic detection of additive outliers is enabled
(outlier.enabled
must be also set to TRUE
).
a logical. If TRUE
, the automatic detection of transitory changes is enabled
(outlier.enabled
must be also set to TRUE
).
a logical. If TRUE
, the automatic detection of level shifts is enabled
(outlier.enabled
must be also set to TRUE
).
a logical. If TRUE
, the automatic detection of seasonal outliers is enabled
(outlier.enabled
must be also set to TRUE
).
a logical. If TRUE
, the critical value for the outlier detection procedure
is automatically determined by the number of observations in the outlier detection time span. If FALSE
,
the procedure uses the entered critical value (outlier.cv
).
a numeric. The entered critical value for the outlier detection procedure.
The modification of this variable is only taken into account when outlier.usedefcv
is set to FALSE
.
determines how the program successively adds detected outliers to the model.
At present, only the AddOne
method is supported.
a numeric. The rate of decay for the transitory change outlier.
a logical. If TRUE
, the automatic modelling of the ARIMA model is enabled.
If FALSE
, the parameters of the ARIMA model can be specified.
Control variables for the automatic modelling of the ARIMA model (when automdl.enabled
is set to TRUE
):
a logical. If TRUE
, the default model (ARIMA(0,1,1)(0,1,1)) may be chosen
in the first step of the automatic model identification. If the Ljung-Box Q statistics for the residuals is acceptable,
the default model is accepted and no further attempt will be made to identify another model.
the cancellation limit (numeric
). If the difference in moduli of an AR and an MA roots
(when estimating ARIMA(1,0,1)(1,0,1) models in the second step of the automatic identification of the differencing orders)
is smaller than the cancellation limit, the two roots are assumed equal and cancel out.
the first unit root limit (numeric
). It is the threshold value for the initial unit root test
in the automatic differencing procedure. When one of the roots in the estimation of the ARIMA(2,0,0)(1,0,0) plus mean model,
performed in the first step of the automatic model identification procedure, is larger than the first unit root limit in modulus,
it is set equal to unity.
the second unit root limit (numeric
). When one of the roots in the estimation of
the ARIMA(1,0,1)(1,0,1) plus mean model, which is performed in the second step of the automatic model identification
procedure, is larger than second unit root limit in modulus, it is checked if there is a common factor
in the corresponding AR and MA polynomials of the ARMA model that can be canceled (see automdl.cancel
).
If there is no cancellation, the AR root is set equal to unity (i.e. the differencing order changes).
a logical. This variable controls whether ARIMA models with non-seasonal AR and MA terms
or seasonal AR and MA terms will be considered in the automatic model identification procedure.
If FALSE
, a model with AR and MA terms in both the seasonal and non-seasonal parts of the model can be acceptable,
provided there are no AR or MA terms in either the seasonal or non-seasonal terms.
a logical. If TRUE
, the automatic model identification procedure will have a preference
for balanced models (i.e. models for which the order of the combined AR and differencing operator is equal to the order
of the combined MA operator).
the ARMA limit (numeric
). It is the threshold value for t-statistics of ARMA coefficients
and constant term used for the final test of model parsimony. If the highest order ARMA coefficient has a t-value
smaller than this value in magnitude, the order of the model is reduced. If the constant term t-value is smaller
than the ARMA limit in magnitude, it is removed from the set of regressors.
numeric, ReduceCV. The percentage by which the outlier's critical value will be reduced when an identified model is found to have a Ljung-Box statistic with an unacceptable confidence coefficient. The parameter should be between 0 and 1, and will only be active when automatic outlier identification is enabled. The reduced critical value will be set to (1-ReduceCV)*CV, where CV is the original critical value.
the Ljung Box limit (numeric
). Acceptance criterion for the confidence intervals
of the Ljung-Box Q statistic. If the LjungBox Q statistics for the residuals of a final model is greater than
the Ljung Box limit, then the model is rejected, the outlier critical value is reduced and model and outlier identification
(if specified) is redone with a reduced value.
numeric, final unit root limit. The threshold value for the final unit root test. If the magnitude of an AR root for the final model is smaller than the final unit root limit, then a unit root is assumed, the order of the AR polynomial is reduced by one and the appropriate order of the differencing (non-seasonal, seasonal) is increased. The parameter value should be greater than one.
Control variables for the non-automatic modelling of the ARIMA model (when automdl.enabled
is set to FALSE
):
logical. If TRUE
, the mean is considered as part of the ARIMA model.
numeric. The order of the non-seasonal autoregressive (AR) polynomial.
numeric. The regular differencing order.
numeric. The order of the non-seasonal moving average (MA) polynomial.
numeric. The order of the seasonal autoregressive (AR) polynomial.
numeric. The seasonal differencing order.
numeric. The order of the seasonal moving average (MA) polynomial.
Control variables for the user-defined ARMA coefficients. Coefficients can be defined for the regular and seasonal
autoregressive (AR) polynomials and moving average (MA) polynomials. The model considers the coefficients only if
the procedure for their estimation (arima.coefType
) is provided, and the number of provided coefficients
matches the sum of (regular and seasonal) AR and MA orders (p,q,bp,bq
).
logical. If TRUE
, the program uses the user-defined ARMA coefficients.
a vector providing the coefficients for the regular and seasonal AR and MA polynomials.
The vector length must be equal to the sum of the regular and seasonal AR and MA orders.
The coefficients shall be provided in the following order: regular AR (Phi; p
elements),
regular MA (Theta; q
elements), seasonal AR (BPhi; bp
elements)
and seasonal MA (BTheta; bq
elements).
E.g.: arima.coef=c(0.6,0.7)
with arima.p=1, arima.q=0,arima.bp=1
and arima.bq=0
.
a vector defining the ARMA coefficients estimation procedure.
Possible procedures are: "Undefined"
= no use of any user-defined input (i.e. coefficients are estimated),
"Fixed"
= the coefficients are fixed at the value provided by the user,
"Initial"
= the value defined by the user is used as the initial condition.
For orders for which the coefficients shall not be defined, the arima.coef
can be set to NA
or 0
,
or the arima.coefType
can be set to "Undefined"
.
E.g.: arima.coef = c(-0.8,-0.6,NA)
, arima.coefType = c("Fixed","Fixed","Undefined")
.
the forecasting horizon (numeric
). The forecast length generated by the RegARIMA model
in periods (positive values) or years (negative values). By default, the program generates a two-year forecast
(fcst.horizon
set to -2
).
The available predefined 'JDemetra+' model specifications are described in the table below:
Identifier | | Log/level detection | | Outliers detection | | Calendar effects | | ARIMA | RG0 | | NA | |
NA | | NA | | Airline(+mean) | RG1 | | automatic | | AO/LS/TC | | NA | |
Airline(+mean) | RG2c | | automatic | | AO/LS/TC | | 2 td vars + Easter | | Airline(+mean) | RG3 | |
automatic | | AO/LS/TC | | NA | | automatic | RG4c | | automatic | | AO/LS/TC | |
2 td vars + Easter | | automatic | RG5c | | automatic | | AO/LS/TC | | 7 td vars + Easter | | automatic |
More information and examples related to 'JDemetra+' features in the online documentation: https://jdemetra-new-documentation.netlify.app/
# \donttest{
myseries <- ipi_c_eu[, "FR"]
myspec1 <- regarima_spec_x13(spec = "RG5c")
myreg1 <- regarima(myseries, spec = myspec1)
# To modify a pre-specified model specification
myspec2 <- regarima_spec_x13(spec = "RG5c",
tradingdays.option = "WorkingDays")
myreg2 <- regarima(myseries, spec = myspec2)
# To modify the model specification of a "regarima" object
myspec3 <- regarima_spec_x13(myreg1, tradingdays.option = "WorkingDays")
myreg3 <- regarima(myseries, myspec3)
# To modify the model specification of a "regarima_spec" object
myspec4 <- regarima_spec_x13(myspec1, tradingdays.option = "WorkingDays")
myreg4 <- regarima(myseries, myspec4)
# Pre-specified outliers
myspec1 <- regarima_spec_x13(spec = "RG5c", usrdef.outliersEnabled = TRUE,
usrdef.outliersType = c("LS", "AO"),
usrdef.outliersDate = c("2008-10-01", "2002-01-01"),
usrdef.outliersCoef = c(36, 14),
transform.function = "None")
myreg1 <- regarima(myseries, myspec1)
myreg1
s_preOut(myreg1)
# User-defined variables
var1 <- ts(rnorm(length(myseries))*10, start = start(myseries),
frequency = 12)
var2 <- ts(rnorm(length(myseries))*100, start = start(myseries),
frequency = 12)
var <- ts.union(var1, var2)
myspec1 <- regarima_spec_x13(spec = "RG5c", usrdef.varEnabled = TRUE,
usrdef.var = var)
myreg1 <- regarima(myseries, myspec1)
myreg1
myspec2 <- regarima_spec_x13(spec = "RG5c", usrdef.varEnabled = TRUE,
usrdef.var = var1, usrdef.varCoef = 2,
transform.function = "None")
myreg2 <- regarima(myseries, myspec2)
s_preVar(myreg2)
# Pre-specified ARMA coefficients
myspec1 <- regarima_spec_x13(spec = "RG5c", automdl.enabled =FALSE,
arima.p = 1, arima.q = 1, arima.bp = 0, arima.bq = 1,
arima.coefEnabled = TRUE, arima.coef = c(-0.8, -0.6, 0),
arima.coefType = c(rep("Fixed", 2), "Undefined"))
s_arimaCoef(myspec1)
myreg1 <- regarima(myseries, myspec1)
myreg1
# }
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