src/library/datasets/man/Nile.Rd - R - Git at Google

 % File src/library/datasets/man/Nile.Rd
 % Part of the R package, https://www.R-project.org
 % Copyright 1995-2018 R Core Team
 % Distributed under GPL 2 or later

 \name{Nile}
 \docType{data}
 \alias{Nile}
 \title{Flow of the River Nile}
 \usage{Nile}
 \description{
   Measurements of the annual flow of the river Nile at Aswan (formerly
   \code{Assuan}), 1871--1970, in \eqn{10^8 m^3},
   \dQuote{with apparent changepoint near 1898} (Cobb(1978), Table 1, p.249).
 }
 \format{
   A time series of length 100.
 }
 \source{
   Durbin, J. and Koopman, S. J. (2001).
   \emph{Time Series Analysis by State Space Methods}.
   Oxford University Press.
   \url{http://www.ssfpack.com/DKbook.html}
 }
 \references{
   Balke, N. S. (1993).
   Detecting level shifts in time series.
   \emph{Journal of Business and Economic Statistics}, \bold{11}, 81--92.
   \doi{10.2307/1391308}.

   Cobb, G. W. (1978).
   The problem of the Nile: conditional solution to a change-point
   problem.
   \emph{Biometrika} \bold{65}, 243--51.
   \doi{10.2307/2335202}.
 }
 \examples{
 require(stats); require(graphics)
 par(mfrow = c(2, 2))
 plot(Nile)
 acf(Nile)
 pacf(Nile)
 ar(Nile) # selects order 2
 cpgram(ar(Nile)$resid)
 par(mfrow = c(1, 1))
 arima(Nile, c(2, 0, 0))

 ## Now consider missing values, following Durbin & Koopman
 NileNA <- Nile
 NileNA[c(21:40, 61:80)] <- NA
 arima(NileNA, c(2, 0, 0))
 plot(NileNA)
 pred <-
    predict(arima(window(NileNA, 1871, 1890), c(2, 0, 0)), n.ahead = 20)
 lines(pred$pred, lty = 3, col = "red")
 lines(pred$pred + 2*pred$se, lty = 2, col = "blue")
 lines(pred$pred - 2*pred$se, lty = 2, col = "blue")
 pred <-
    predict(arima(window(NileNA, 1871, 1930), c(2, 0, 0)), n.ahead = 20)
 lines(pred$pred, lty = 3, col = "red")
 lines(pred$pred + 2*pred$se, lty = 2, col = "blue")
 lines(pred$pred - 2*pred$se, lty = 2, col = "blue")

 ## Structural time series models
 par(mfrow = c(3, 1))
 plot(Nile)
 ## local level model
 (fit <- StructTS(Nile, type = "level"))
 lines(fitted(fit), lty = 2)              # contemporaneous smoothing
 lines(tsSmooth(fit), lty = 2, col = 4)   # fixed-interval smoothing
 plot(residuals(fit)); abline(h = 0, lty = 3)
 ## local trend model
 (fit2 <- StructTS(Nile, type = "trend")) ## constant trend fitted
 pred <- predict(fit, n.ahead = 30)
 ## with 50\% confidence interval
 ts.plot(Nile, pred$pred,
         pred$pred + 0.67*pred$se, pred$pred -0.67*pred$se)

 ## Now consider missing values
 plot(NileNA)
 (fit3 <- StructTS(NileNA, type = "level"))
 lines(fitted(fit3), lty = 2)
 lines(tsSmooth(fit3), lty = 3)
 plot(residuals(fit3)); abline(h = 0, lty = 3)
 }
 \keyword{datasets}
	% File src/library/datasets/man/Nile.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2018 R Core Team
	% Distributed under GPL 2 or later

	\name{Nile}
	\docType{data}
	\alias{Nile}
	\title{Flow of the River Nile}
	\usage{Nile}
	\description{
	Measurements of the annual flow of the river Nile at Aswan (formerly
	\code{Assuan}), 1871--1970, in \eqn{10^8 m^3},
	\dQuote{with apparent changepoint near 1898} (Cobb(1978), Table 1, p.249).
	}
	\format{
	A time series of length 100.
	}
	\source{
	Durbin, J. and Koopman, S. J. (2001).
	\emph{Time Series Analysis by State Space Methods}.
	Oxford University Press.
	\url{http://www.ssfpack.com/DKbook.html}
	}
	\references{
	Balke, N. S. (1993).
	Detecting level shifts in time series.
	\emph{Journal of Business and Economic Statistics}, \bold{11}, 81--92.
	\doi{10.2307/1391308}.

	Cobb, G. W. (1978).
	The problem of the Nile: conditional solution to a change-point
	problem.
	\emph{Biometrika} \bold{65}, 243--51.
	\doi{10.2307/2335202}.
	}
	\examples{
	require(stats); require(graphics)
	par(mfrow = c(2, 2))
	plot(Nile)
	acf(Nile)
	pacf(Nile)
	ar(Nile) # selects order 2
	cpgram(ar(Nile)$resid)
	par(mfrow = c(1, 1))
	arima(Nile, c(2, 0, 0))

	## Now consider missing values, following Durbin & Koopman
	NileNA <- Nile
	NileNA[c(21:40, 61:80)] <- NA
	arima(NileNA, c(2, 0, 0))
	plot(NileNA)
	pred <-
	predict(arima(window(NileNA, 1871, 1890), c(2, 0, 0)), n.ahead = 20)
	lines(pred$pred, lty = 3, col = "red")
	lines(pred$pred + 2*pred$se, lty = 2, col = "blue")
	lines(pred$pred - 2*pred$se, lty = 2, col = "blue")
	pred <-
	predict(arima(window(NileNA, 1871, 1930), c(2, 0, 0)), n.ahead = 20)
	lines(pred$pred, lty = 3, col = "red")
	lines(pred$pred + 2*pred$se, lty = 2, col = "blue")
	lines(pred$pred - 2*pred$se, lty = 2, col = "blue")

	## Structural time series models
	par(mfrow = c(3, 1))
	plot(Nile)
	## local level model
	(fit <- StructTS(Nile, type = "level"))
	lines(fitted(fit), lty = 2) # contemporaneous smoothing
	lines(tsSmooth(fit), lty = 2, col = 4) # fixed-interval smoothing
	plot(residuals(fit)); abline(h = 0, lty = 3)
	## local trend model
	(fit2 <- StructTS(Nile, type = "trend")) ## constant trend fitted
	pred <- predict(fit, n.ahead = 30)
	## with 50\% confidence interval
	ts.plot(Nile, pred$pred,
	pred$pred + 0.67pred$se, pred$pred -0.67pred$se)

	## Now consider missing values
	plot(NileNA)
	(fit3 <- StructTS(NileNA, type = "level"))
	lines(fitted(fit3), lty = 2)
	lines(tsSmooth(fit3), lty = 3)
	plot(residuals(fit3)); abline(h = 0, lty = 3)
	}
	\keyword{datasets}