gls(model, data, correlation, weights, subset, method, na.action,
control, verbose)
## S3 method for class 'gls':
update(object, model., \dots, evaluate = TRUE)gls, representing
a generalized least squares fitted linear model.~ operator and the
terms, separated by + operators, on the right.update.formula for
details.model, correlation, weights, and
subset. By default the variables are taken from the
environment from which gls is called.corStruct object describing the
within-group correlation structure. See the documentation of
corClasses for a description of the available corStruct
classes. If a grouping variable is to be used,varFunc object or one-sided formula
describing the within-group heteroscedasticity structure. If given as
a formula, it is used as the argument to varFixed,
corresponding to fixed variance weights. See the dodata should be used in the fit. This can be a logical
vector, or a numeric vector indicating which observation numbers are
to be included, or a character vector of the"REML" the model is fit by
maximizing the restricted log-likelihood. If "ML" the
log-likelihood is maximized. Defaults to "REML".NAs. The default action (na.fail) causes
gls to print an error message and terminate if there are any
incomplete observations.glsControl.
Defaults to an empty list.TRUE information on
the evolution of the iterative algorithm is printed. Default is
FALSE.TRUE evaluate the new call else return the call.gls representing the linear model
fit. Generic functions such as print, plot, and
summary have methods to show the results of the fit. See
glsObject for the components of the fit. The functions
resid, coef, and fitted can be used to extract
some of its components.correlation argument are described in Box, G.E.P., Jenkins,
G.M., and Reinsel G.C. (1994), Littel, R.C., Milliken, G.A., Stroup,
W.W., and Wolfinger, R.D. (1996), and Venables, W.N. and Ripley,
B.D. (1997). The use of variance functions for linear
and nonlinear models is presented in detail in Carroll, R.J. and Ruppert,
D. (1988) and Davidian, M. and Giltinan, D.M. (1995). Box, G.E.P., Jenkins, G.M., and Reinsel G.C. (1994) "Time Series Analysis: Forecasting and Control", 3rd Edition, Holden-Day.
Carroll, R.J. and Ruppert, D. (1988) "Transformation and Weighting in Regression", Chapman and Hall.
Davidian, M. and Giltinan, D.M. (1995) "Nonlinear Mixed Effects Models for Repeated Measurement Data", Chapman and Hall.
Littel, R.C., Milliken, G.A., Stroup, W.W., and Wolfinger, R.D. (1996) "SAS Systems for Mixed Models", SAS Institute.
Pinheiro, J.C., and Bates, D.M. (2000) "Mixed-Effects Models in S and S-PLUS", Springer, esp. pp. 100, 461.
Venables, W.N. and Ripley, B.D. (1997) "Modern Applied Statistics with S-PLUS", 2nd Edition, Springer-Verlag.
corClasses,
glsControl,
glsObject,
glsStruct,
plot.gls,
predict.gls,
qqnorm.gls,
residuals.gls,
summary.gls,
varClasses,
varFunc# AR(1) errors within each Mare
fm1 <- gls(follicles ~ sin(2*pi*Time) + cos(2*pi*Time), Ovary,
correlation = corAR1(form = ~ 1 | Mare))
# variance increases as a power of the absolute fitted values
fm2 <- update(fm1, weights = varPower())Run the code above in your browser using DataLab