auto.ar: Sparse AR(p)
In bsts: Bayesian Structural Time Series
auto.ar R Documentation
Sparse AR(p)
Description
Add a sparse AR(p) process to the state distribution. A
sparse AR(p) is an AR(p) process with a spike and slab prior on the
autoregression coefficients.
Usage
AddAutoAr(state.specification,
y,
lags = 1,
prior = NULL,
sdy = NULL,
...)
Arguments
state.specification
A list of state components. If omitted,
an empty list is assumed.
y
A numeric vector. The time series to be modeled. This can
be omitted if sdy is supplied.
lags
The maximum number of lags ("p") to be considered in the AR(p) process.
prior
An object inheriting from SpikeSlabArPrior, or
NULL. If the latter, then a default
SpikeSlabArPrior will be created.
sdy
The sample standard deviation of the time series to be
modeled. Used to scale the prior distribution. This can be omitted
if y is supplied.
...
Extra arguments passed to SpikeSlabArPrior.
Details
The model contributes alpha[t] to the expected value of y[t], where
the transition equation is
\alpha_{t} = \phi_1\alpha_{i, t-1} + \cdots + \phi_p
\alpha_{t-p} + \epsilon_{t-1} \qquad
\epsilon_t \sim \mathcal{N}(0, \sigma^2)
The state consists of the last p lags of alpha. The
state transition matrix has phi in its first row, ones along
its first subdiagonal, and zeros elsewhere. The state variance matrix
has sigma^2 in its upper left corner and is zero elsewhere.
The observation matrix has 1 in its first element and is zero
otherwise.
This model differs from the one in AddAr only in that
some of its coefficients may be set to zero.
Value
Returns state.specification with an AR(p) state component
added to the end.
Author(s)
Steven L. Scott steve.the.bayesian@gmail.com
References
Harvey (1990), "Forecasting, structural time series, and the Kalman
filter", Cambridge University Press.
Durbin and Koopman (2001), "Time series analysis by state space
methods", Oxford University Press.
See Also
bsts.
SdPrior
Examples
n <- 100
residual.sd <- .001
# Actual values of the AR coefficients
true.phi <- c(-.7, .3, .15)
ar <- arima.sim(model = list(ar = true.phi),
n = n,
sd = 3)
## Layer some noise on top of the AR process.
y <- ar + rnorm(n, 0, residual.sd)
ss <- AddAutoAr(list(), y, lags = 6)
# Fit the model with knowledge with residual.sd essentially fixed at the
# true value.
model <- bsts(y, state.specification=ss, niter = 500, prior = SdPrior(residual.sd, 100000))
# Now compare the empirical ACF to the true ACF.
acf(y, lag.max = 30)
points(0:30, ARMAacf(ar = true.phi, lag.max = 30), pch = "+")
points(0:30, ARMAacf(ar = colMeans(model$AR6.coefficients), lag.max = 30))
legend("topright", leg = c("empirical", "truth", "MCMC"), pch = c(NA, "+", "o"))
bsts documentation built on May 29, 2024, 2:14 a.m.
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| auto.ar | R Documentation |
Sparse AR(p)
Description
Add a sparse AR(p) process to the state distribution. A sparse AR(p) is an AR(p) process with a spike and slab prior on the autoregression coefficients.
Usage
AddAutoAr(state.specification,
y,
lags = 1,
prior = NULL,
sdy = NULL,
...)
Arguments
state.specification |
A list of state components. If omitted, an empty list is assumed. |
y |
A numeric vector. The time series to be modeled. This can
be omitted if |
lags |
The maximum number of lags ("p") to be considered in the AR(p) process. |
prior |
An object inheriting from |
sdy |
The sample standard deviation of the time series to be
modeled. Used to scale the prior distribution. This can be omitted
if |
... |
Extra arguments passed to |
Details
The model contributes alpha[t] to the expected value of y[t], where the transition equation is
\alpha_{t} = \phi_1\alpha_{i, t-1} + \cdots + \phi_p
\alpha_{t-p} + \epsilon_{t-1} \qquad
\epsilon_t \sim \mathcal{N}(0, \sigma^2)
The state consists of the last p lags of alpha. The
state transition matrix has phi in its first row, ones along
its first subdiagonal, and zeros elsewhere. The state variance matrix
has sigma^2 in its upper left corner and is zero elsewhere.
The observation matrix has 1 in its first element and is zero
otherwise.
This model differs from the one in AddAr only in that
some of its coefficients may be set to zero.
Value
Returns state.specification with an AR(p) state component
added to the end.
Author(s)
Steven L. Scott steve.the.bayesian@gmail.com
References
Harvey (1990), "Forecasting, structural time series, and the Kalman filter", Cambridge University Press.
Durbin and Koopman (2001), "Time series analysis by state space methods", Oxford University Press.
See Also
bsts.
SdPrior
Examples
n <- 100
residual.sd <- .001
# Actual values of the AR coefficients
true.phi <- c(-.7, .3, .15)
ar <- arima.sim(model = list(ar = true.phi),
n = n,
sd = 3)
## Layer some noise on top of the AR process.
y <- ar + rnorm(n, 0, residual.sd)
ss <- AddAutoAr(list(), y, lags = 6)
# Fit the model with knowledge with residual.sd essentially fixed at the
# true value.
model <- bsts(y, state.specification=ss, niter = 500, prior = SdPrior(residual.sd, 100000))
# Now compare the empirical ACF to the true ACF.
acf(y, lag.max = 30)
points(0:30, ARMAacf(ar = true.phi, lag.max = 30), pch = "+")
points(0:30, ARMAacf(ar = colMeans(model$AR6.coefficients), lag.max = 30))
legend("topright", leg = c("empirical", "truth", "MCMC"), pch = c(NA, "+", "o"))
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