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

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

 \name{BOD}
 \docType{data}
 \alias{BOD}
 \title{ Biochemical Oxygen Demand }
 \description{
   The \code{BOD} data frame has 6 rows and 2 columns giving the
   biochemical oxygen demand versus time in an evaluation of water
   quality.
 }
 \usage{BOD}
 \format{
   This data frame contains the following columns:
   \describe{
     \item{\code{Time}}{
       A numeric vector giving the time of the measurement (days).
     }
     \item{\code{demand}}{
       A numeric vector giving the biochemical oxygen demand (mg/l).
     }
   }
 }
 \source{
   Bates, D.M. and Watts, D.G. (1988),
   \emph{Nonlinear Regression Analysis and Its Applications},
   Wiley, Appendix A1.4.

   Originally from Marske (1967), \emph{Biochemical
     Oxygen Demand Data Interpretation Using Sum of Squares Surface}
   M.Sc. Thesis, University of Wisconsin -- Madison.
 }
 \examples{
 \dontshow{options(show.nls.convergence=FALSE)
 old <- options(digits = 5)}
 require(stats)
 # simplest form of fitting a first-order model to these data
 fm1 <- nls(demand ~ A*(1-exp(-exp(lrc)*Time)), data = BOD,
    start = c(A = 20, lrc = log(.35)))
 coef(fm1)
 fm1
 # using the plinear algorithm
 fm2 <- nls(demand ~ (1-exp(-exp(lrc)*Time)), data = BOD,
    start = c(lrc = log(.35)), algorithm = "plinear", trace = TRUE)
 # using a self-starting model
 fm3 <- nls(demand ~ SSasympOrig(Time, A, lrc), data = BOD)
 summary(fm3)
 \dontshow{options(old)}
 }
 \keyword{datasets}
	% File src/library/datasets/man/BOD.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2014 R Core Team
	% Distributed under GPL 2 or later

	\name{BOD}
	\docType{data}
	\alias{BOD}
	\title{ Biochemical Oxygen Demand }
	\description{
	The \code{BOD} data frame has 6 rows and 2 columns giving the
	biochemical oxygen demand versus time in an evaluation of water
	quality.
	}
	\usage{BOD}
	\format{
	This data frame contains the following columns:
	\describe{
	\item{\code{Time}}{
	A numeric vector giving the time of the measurement (days).
	}
	\item{\code{demand}}{
	A numeric vector giving the biochemical oxygen demand (mg/l).
	}
	}
	}
	\source{
	Bates, D.M. and Watts, D.G. (1988),
	\emph{Nonlinear Regression Analysis and Its Applications},
	Wiley, Appendix A1.4.

	Originally from Marske (1967), \emph{Biochemical
	Oxygen Demand Data Interpretation Using Sum of Squares Surface}
	M.Sc. Thesis, University of Wisconsin -- Madison.
	}
	\examples{
	\dontshow{options(show.nls.convergence=FALSE)
	old <- options(digits = 5)}
	require(stats)
	# simplest form of fitting a first-order model to these data
	fm1 <- nls(demand ~ A(1-exp(-exp(lrc)Time)), data = BOD,
	start = c(A = 20, lrc = log(.35)))
	coef(fm1)
	fm1
	# using the plinear algorithm
	fm2 <- nls(demand ~ (1-exp(-exp(lrc)*Time)), data = BOD,
	start = c(lrc = log(.35)), algorithm = "plinear", trace = TRUE)
	# using a self-starting model
	fm3 <- nls(demand ~ SSasympOrig(Time, A, lrc), data = BOD)
	summary(fm3)
	\dontshow{options(old)}
	}
	\keyword{datasets}