sim_pc: Simulate periodically correlated ARMA series
In GeoBosh/pcts: Periodically Correlated and Periodically Integrated Time Series
sim_pc R Documentation
Simulate periodically correlated ARMA series
Description
Simulate a realization of a periodically correlated arma model
or a continuation of an existing series.
Initial values may be given too.
Usage
sim_pc(model, n = NA, randgen = rnorm, seasonof1st = 1, nepochs = NA,
n.start = NA, x, eps, nmean = NULL, nintercept = NULL, ...)
Arguments
model
a list with elements
phi, theta, p, q, period,
mean, intercept,
specifying the model.
n
length of the series.
randgen
random number generator as required by
sim_pwn.
seasonof1st
season of the first value.
nepochs
number of epochs; if nepochs is given, then n is
computed as nepochs * period.
n.start
burn-in number; generate \code{n.start + n} observations and
discard the first n.start of them, see Details.
x
initial or before values, see Details.
eps
innovations, see Details.
nmean
a vector of length n of means, see Details.
nintercept
a vector of length n of intercepts, see Details.
...
any additional arguments to be passed on to sim_pwn.
Details
Argument x can be used to specify two types of initialisation
values - ‘before’ and ‘init’. They are used similarly in computations
but ‘before’ values are not included in the result, while ‘init’
values are (unless dropped due to n.start). ‘Before’ values
provide a convenient way to simulate continuation trajectories for a
time series, for example for simulation based prediction intervals.
If x is "numeric", it represents ‘before’
values. Alternatively, x can be a list with components
"before" and "init".
Innovations are usually generated with the random number generator
specified by randgen (with default rnorm) and the
... parameters by a call to the function sim_pwn, see
the documentation for sim_pwn for various ways to control the
distribution of the generated sequence.
The innovations can also be generated in advance and supplied using
argument eps. If eps is numeric, it is taken to
represent the innovations. Alternatively, eps can be a list
with the innovations in component "main". This list may also
contain components "before" and/or "init" specifying
‘before’ or ‘initial’ values, with interpretation as for x.
nintercept can be used to specify trend representing the effect
of time and/or covariates. As for eps, if it is numeric it is
taken to represent the main values. It can also be a list with
components before, init, and main.
To avoid ambiguity, let's reiterate that before values are past
values of the corresponding quantity (before the start of the
simulated series), while init values are "initial" values. In
particular, if initial values are specified for x, these will
form the start of the generated series (unless n.start leads to
them being discarded).
If before values are specified for the series and the
innovations, then they play a role analogous to that of initial
values, so it does not make much sense to supply also initial
values.
The function effectively does the following.
innov is generated if not supplied,
a vector of innovations is created
eps <- c(innovbefore,innovinit,innov),
a vector x is created of the same length as eps,
and initialised with xbefore and xinit.
If there are no initial or before values, these are assumed to be 0.
The remaining values of x are filled using the pc-arma equations.
Finally, the xbefore values are discarded as well as the first
n.start values.
n.start should usually be a multiple of the period since
otherwise the first observation in the returned vector will not
correspond to seasonof1st.
sim_pc deals mainly with the interpretation of the parameters.
The actual computations are done by pc.filter. Moreover,
sim_pc does not look at the model. It knows only about
model$period and uses it to compute n if n is not
specified.
(It probably should not care even about this.)
Value
numeric, the simulated time series
To do
option to return the innovation sequence;
option to include the before values.
option to return the season of the first value in the returned series
(it may be different from seasonof1st due to n.start).
Author(s)
Georgi N. Boshnakov
See Also
sim_pwn, pc.filter
Examples
m1 <- rbind( c(1, 0.81, 0), c(1, 0.4972376, 0.4972376) )
testphi <- slMatrix( init = m1 )
m2 <- rbind( c(1, 0, 0), c(1, 0, 0) )
testtheta <- slMatrix( init = m2 )
## phi and theta are slMatrix here.
mo1 <- list(phi = testphi, theta = testtheta, p = 2, q = 2, period = 2)
set.seed(1234)
a1 <- sim_pc(mo1, 100)
## phi and theta are ordinary matrices here.
mo2 <- list(phi = m1[ , 2:ncol(m1)], theta = m2[ , 2:ncol(m2)], p = 2, q = 2, period = 2)
set.seed(1234)
a2 <- sim_pc(mo2, 100)
identical(a1, a2)
## Lina's PAR model
parcoef <- rbind(c(0.5, -0.06), c(0.6, -0.08),
c(0.7, -0.1), c(0.2, 0.15) )
picoef1 <- c(0.8, 1.25, 2, 0.5)
parcoef2 <- pi1ar2par(picoef1, parcoef)
picoef2 <- c(4, 0.25, 5, 0.2)
coefper2I2 <- pi1ar2par(picoef2, parcoef2)
#### specify the model using multi-companion approach
mc2I2 <- mcompanion::mc_from_filter(coefper2I2)
co2I2 <- eigen(mc2I2)$vectors
co2I2
m2I2 <- mcompanion::sim_pcfilter(period = 4, n.root = 4,
eigabs = c(1, 0.036568887, 0.001968887),
eigsign = c(1, 1, -1),
len.block = c(2, 1, 1),
type.eigval = c("r", "r", "r"),
co = cbind(co2I2[ ,1], rep(NA, 4), co2I2[,3:4]))
m2I2$pcfilter
perunit2mc <- sim_pc(list(phi = m2I2$pcfilter, p = 4, q = 0, period = 4), 500)
plot(perunit2mc)
plot(perunit2mc, type = "p")
# todo: give example with sigmat^2 !!!
GeoBosh/pcts documentation built on Dec. 8, 2023, 9:57 p.m.
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| sim_pc | R Documentation |
Simulate periodically correlated ARMA series
Description
Simulate a realization of a periodically correlated arma model or a continuation of an existing series. Initial values may be given too.
Usage
sim_pc(model, n = NA, randgen = rnorm, seasonof1st = 1, nepochs = NA,
n.start = NA, x, eps, nmean = NULL, nintercept = NULL, ...)
Arguments
model |
a list with elements
|
n |
length of the series. |
randgen |
random number generator as required by
|
seasonof1st |
season of the first value. |
nepochs |
number of epochs; if |
n.start |
burn-in number; generate |
x |
initial or before values, see Details. |
eps |
innovations, see Details. |
nmean |
a vector of length |
nintercept |
a vector of length |
... |
any additional arguments to be passed on to |
Details
Argument x can be used to specify two types of initialisation
values - ‘before’ and ‘init’. They are used similarly in computations
but ‘before’ values are not included in the result, while ‘init’
values are (unless dropped due to n.start). ‘Before’ values
provide a convenient way to simulate continuation trajectories for a
time series, for example for simulation based prediction intervals.
If x is "numeric", it represents ‘before’
values. Alternatively, x can be a list with components
"before" and "init".
Innovations are usually generated with the random number generator
specified by randgen (with default rnorm) and the
... parameters by a call to the function sim_pwn, see
the documentation for sim_pwn for various ways to control the
distribution of the generated sequence.
The innovations can also be generated in advance and supplied using
argument eps. If eps is numeric, it is taken to
represent the innovations. Alternatively, eps can be a list
with the innovations in component "main". This list may also
contain components "before" and/or "init" specifying
‘before’ or ‘initial’ values, with interpretation as for x.
nintercept can be used to specify trend representing the effect
of time and/or covariates. As for eps, if it is numeric it is
taken to represent the main values. It can also be a list with
components before, init, and main.
To avoid ambiguity, let's reiterate that before values are past
values of the corresponding quantity (before the start of the
simulated series), while init values are "initial" values. In
particular, if initial values are specified for x, these will
form the start of the generated series (unless n.start leads to
them being discarded).
If before values are specified for the series and the innovations, then they play a role analogous to that of initial values, so it does not make much sense to supply also initial values.
The function effectively does the following.
innov is generated if not supplied,
a vector of innovations is created
eps <- c(innovbefore,innovinit,innov),
a vector x is created of the same length as eps,
and initialised with xbefore and xinit.
If there are no initial or before values, these are assumed to be 0.
The remaining values of x are filled using the pc-arma equations.
Finally, the xbefore values are discarded as well as the first
n.start values.
n.start should usually be a multiple of the period since
otherwise the first observation in the returned vector will not
correspond to seasonof1st.
sim_pc deals mainly with the interpretation of the parameters.
The actual computations are done by pc.filter. Moreover,
sim_pc does not look at the model. It knows only about
model$period and uses it to compute n if n is not
specified.
(It probably should not care even about this.)
Value
numeric, the simulated time series
To do
option to return the innovation sequence; option to include the before values.
option to return the season of the first value in the returned series
(it may be different from seasonof1st due to n.start).
Author(s)
Georgi N. Boshnakov
See Also
sim_pwn, pc.filter
Examples
m1 <- rbind( c(1, 0.81, 0), c(1, 0.4972376, 0.4972376) )
testphi <- slMatrix( init = m1 )
m2 <- rbind( c(1, 0, 0), c(1, 0, 0) )
testtheta <- slMatrix( init = m2 )
## phi and theta are slMatrix here.
mo1 <- list(phi = testphi, theta = testtheta, p = 2, q = 2, period = 2)
set.seed(1234)
a1 <- sim_pc(mo1, 100)
## phi and theta are ordinary matrices here.
mo2 <- list(phi = m1[ , 2:ncol(m1)], theta = m2[ , 2:ncol(m2)], p = 2, q = 2, period = 2)
set.seed(1234)
a2 <- sim_pc(mo2, 100)
identical(a1, a2)
## Lina's PAR model
parcoef <- rbind(c(0.5, -0.06), c(0.6, -0.08),
c(0.7, -0.1), c(0.2, 0.15) )
picoef1 <- c(0.8, 1.25, 2, 0.5)
parcoef2 <- pi1ar2par(picoef1, parcoef)
picoef2 <- c(4, 0.25, 5, 0.2)
coefper2I2 <- pi1ar2par(picoef2, parcoef2)
#### specify the model using multi-companion approach
mc2I2 <- mcompanion::mc_from_filter(coefper2I2)
co2I2 <- eigen(mc2I2)$vectors
co2I2
m2I2 <- mcompanion::sim_pcfilter(period = 4, n.root = 4,
eigabs = c(1, 0.036568887, 0.001968887),
eigsign = c(1, 1, -1),
len.block = c(2, 1, 1),
type.eigval = c("r", "r", "r"),
co = cbind(co2I2[ ,1], rep(NA, 4), co2I2[,3:4]))
m2I2$pcfilter
perunit2mc <- sim_pc(list(phi = m2I2$pcfilter, p = 4, q = 0, period = 4), 500)
plot(perunit2mc)
plot(perunit2mc, type = "p")
# todo: give example with sigmat^2 !!!
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