src/library/stats/man/ar.ols.Rd - R - Git at Google

 % File src/library/stats/man/ar.ols.Rd
 % Part of the R package, https://www.R-project.org
 % Copyright 1995-2014 R Core Team
 % Distributed under GPL 2 or later

 \name{ar.ols}
 \alias{ar.ols}
 \title{Fit Autoregressive Models to Time Series by OLS}
 \usage{
 ar.ols(x, aic = TRUE, order.max = NULL, na.action = na.fail,
        demean = TRUE, intercept = demean, series, \dots)
 }
 \arguments{
   \item{x}{A univariate or multivariate time series.}

   \item{aic}{Logical flag.  If \code{TRUE} then the Akaike Information
     Criterion is used to choose the order of the autoregressive
     model. If \code{FALSE}, the model of order \code{order.max} is
     fitted.}

   \item{order.max}{Maximum order (or order) of model to fit. Defaults
     to \eqn{10\log_{10}(N)}{10*log10(N)} where \eqn{N} is the number
     of observations.}

   \item{na.action}{function to be called to handle missing values.}

   \item{demean}{should the AR model be for \code{x} minus its mean?}

   \item{intercept}{should a separate intercept term be fitted?}

   \item{series}{names for the series.  Defaults to
     \code{deparse(substitute(x))}.}

   \item{\dots}{further arguments to be passed to or from methods.}
 }
 \description{
   Fit an autoregressive time series model to the data by ordinary
   least squares, by default selecting the complexity by AIC.
 }
 \details{
   \code{ar.ols} fits the general AR model to a possibly non-stationary
   and/or multivariate system of series \code{x}. The resulting
   unconstrained least squares estimates are consistent, even if
   some of the series are non-stationary and/or co-integrated.
   For definiteness, note that the AR coefficients have the sign in

   \deqn{x_t - \mu = a_0 + a_1(x_{t-1} - \mu) + \cdots + a_p(x_{t-p} - \mu) + e_t}{(x[t] - m) = a[0] + a[1]*(x[t-1] - m) + \dots +  a[p]*(x[t-p] - m) + e[t]}

   where \eqn{a_0}{a[0]} is zero unless \code{intercept} is true, and
   \eqn{\mu}{m} is the sample mean if \code{demean} is true, zero
   otherwise.

   Order selection is done by AIC if \code{aic} is true. This is
   problematic, as \code{ar.ols} does not perform
   true maximum likelihood estimation. The AIC is computed as if
   the variance estimate (computed from the variance matrix of the
   residuals) were the MLE, omitting the determinant term from the
   likelihood. Note that this is not the same as the Gaussian
   likelihood evaluated at the estimated parameter values.

   Some care is needed if \code{intercept} is true and \code{demean} is
   false. Only use this is the series are roughly centred on
   zero. Otherwise the computations may be inaccurate or fail entirely.
 }
 \value{
   A list of class \code{"ar"} with the following elements:
   \item{order}{The order of the fitted model.  This is chosen by
     minimizing the AIC if \code{aic = TRUE}, otherwise it is
     \code{order.max}.}
   \item{ar}{Estimated autoregression coefficients for the fitted
     model.}
   \item{var.pred}{The prediction variance: an estimate of the portion of
     the variance of the time series that is not explained by the
     autoregressive model.}
   \item{x.mean}{The estimated mean (or zero if \code{demean} is false)
     of the series used in fitting and for use in prediction.}
   \item{x.intercept}{The intercept in the model for
     \code{x - x.mean}, or zero if \code{intercept} is false.}
   \item{aic}{The differences in AIC between each model and the
     best-fitting model.  Note that the latter can have an AIC of \code{-Inf}.}
   \item{n.used}{The number of observations in the time series.}
   \item{order.max}{The value of the \code{order.max} argument.}
   \item{partialacf}{\code{NULL}.  For compatibility with \code{ar}.}
   \item{resid}{residuals from the fitted model, conditioning on the
     first \code{order} observations.  The first \code{order} residuals
     are set to \code{NA}. If \code{x} is a time series, so is
     \code{resid}.}
   \item{method}{The character string \code{"Unconstrained LS"}.}
   \item{series}{The name(s) of the time series.}
   \item{frequency}{The frequency of the time series.}
   \item{call}{The matched call.}
   \item{asy.se.coef}{The asymptotic-theory standard errors of the
     coefficient estimates.}
 }
 \author{Adrian Trapletti, Brian Ripley.}
 \seealso{
   \code{\link{ar}}
 }
 \references{
   Luetkepohl, H. (1991): \emph{Introduction to Multiple Time Series
     Analysis.} Springer Verlag, NY, pp.\sspace{}368--370.
 }
 \examples{
 ar(lh, method = "burg")
 ar.ols(lh)
 ar.ols(lh, FALSE, 4) # fit ar(4)

 ar.ols(ts.union(BJsales, BJsales.lead))

 x <- diff(log(EuStockMarkets))
 ar.ols(x, order.max = 6, demean = FALSE, intercept = TRUE)
 }
 \keyword{ts}
	% File src/library/stats/man/ar.ols.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2014 R Core Team
	% Distributed under GPL 2 or later

	\name{ar.ols}
	\alias{ar.ols}
	\title{Fit Autoregressive Models to Time Series by OLS}
	\usage{
	ar.ols(x, aic = TRUE, order.max = NULL, na.action = na.fail,
	demean = TRUE, intercept = demean, series, \dots)
	}
	\arguments{
	\item{x}{A univariate or multivariate time series.}

	\item{aic}{Logical flag. If \code{TRUE} then the Akaike Information
	Criterion is used to choose the order of the autoregressive
	model. If \code{FALSE}, the model of order \code{order.max} is
	fitted.}

	\item{order.max}{Maximum order (or order) of model to fit. Defaults
	to \eqn{10\log_{10}(N)}{10*log10(N)} where \eqn{N} is the number
	of observations.}

	\item{na.action}{function to be called to handle missing values.}

	\item{demean}{should the AR model be for \code{x} minus its mean?}

	\item{intercept}{should a separate intercept term be fitted?}

	\item{series}{names for the series. Defaults to
	\code{deparse(substitute(x))}.}

	\item{\dots}{further arguments to be passed to or from methods.}
	}
	\description{
	Fit an autoregressive time series model to the data by ordinary
	least squares, by default selecting the complexity by AIC.
	}
	\details{
	\code{ar.ols} fits the general AR model to a possibly non-stationary
	and/or multivariate system of series \code{x}. The resulting
	unconstrained least squares estimates are consistent, even if
	some of the series are non-stationary and/or co-integrated.
	For definiteness, note that the AR coefficients have the sign in

	\deqn{x_t - \mu = a_0 + a_1(x_{t-1} - \mu) + \cdots + a_p(x_{t-p} - \mu) + e_t}{(x[t] - m) = a[0] + a[1](x[t-1] - m) + \dots + a[p](x[t-p] - m) + e[t]}

	where \eqn{a_0}{a[0]} is zero unless \code{intercept} is true, and
	\eqn{\mu}{m} is the sample mean if \code{demean} is true, zero
	otherwise.

	Order selection is done by AIC if \code{aic} is true. This is
	problematic, as \code{ar.ols} does not perform
	true maximum likelihood estimation. The AIC is computed as if
	the variance estimate (computed from the variance matrix of the
	residuals) were the MLE, omitting the determinant term from the
	likelihood. Note that this is not the same as the Gaussian
	likelihood evaluated at the estimated parameter values.

	Some care is needed if \code{intercept} is true and \code{demean} is
	false. Only use this is the series are roughly centred on
	zero. Otherwise the computations may be inaccurate or fail entirely.
	}
	\value{
	A list of class \code{"ar"} with the following elements:
	\item{order}{The order of the fitted model. This is chosen by
	minimizing the AIC if \code{aic = TRUE}, otherwise it is
	\code{order.max}.}
	\item{ar}{Estimated autoregression coefficients for the fitted
	model.}
	\item{var.pred}{The prediction variance: an estimate of the portion of
	the variance of the time series that is not explained by the
	autoregressive model.}
	\item{x.mean}{The estimated mean (or zero if \code{demean} is false)
	of the series used in fitting and for use in prediction.}
	\item{x.intercept}{The intercept in the model for
	\code{x - x.mean}, or zero if \code{intercept} is false.}
	\item{aic}{The differences in AIC between each model and the
	best-fitting model. Note that the latter can have an AIC of \code{-Inf}.}
	\item{n.used}{The number of observations in the time series.}
	\item{order.max}{The value of the \code{order.max} argument.}
	\item{partialacf}{\code{NULL}. For compatibility with \code{ar}.}
	\item{resid}{residuals from the fitted model, conditioning on the
	first \code{order} observations. The first \code{order} residuals
	are set to \code{NA}. If \code{x} is a time series, so is
	\code{resid}.}
	\item{method}{The character string \code{"Unconstrained LS"}.}
	\item{series}{The name(s) of the time series.}
	\item{frequency}{The frequency of the time series.}
	\item{call}{The matched call.}
	\item{asy.se.coef}{The asymptotic-theory standard errors of the
	coefficient estimates.}
	}
	\author{Adrian Trapletti, Brian Ripley.}
	\seealso{
	\code{\link{ar}}
	}
	\references{
	Luetkepohl, H. (1991): \emph{Introduction to Multiple Time Series
	Analysis.} Springer Verlag, NY, pp.\sspace{}368--370.
	}
	\examples{
	ar(lh, method = "burg")
	ar.ols(lh)
	ar.ols(lh, FALSE, 4) # fit ar(4)

	ar.ols(ts.union(BJsales, BJsales.lead))

	x <- diff(log(EuStockMarkets))
	ar.ols(x, order.max = 6, demean = FALSE, intercept = TRUE)
	}
	\keyword{ts}