asis,
pol,
lsp
,
rcs,
catg,
scored,
strat,
matrx), fitting functions
(e.g.,
lrm,
cph,
psm, or
ols), and generic analysis functions
(
anova.Design,
summary.Design,
predict.Design,
plot.Design
,
survplot,
fastbw
,
validate,
calibrate,
specs.Design,
which.influence
,
latex.Design,
nomogram.Design,
datadist,
gendata)
that help automate many
analysis steps, e.g. fitting restricted interactions and multiple
stratification variables, analysis of variance (with tests of linearity
of each factor and pooled tests), plotting effects of variables in the
model, estimating and graphing effects of variables that appear non-linearly in the
model using e.g. inter-quartile-range hazard ratios, bootstrapping
model fits, and constructing nomograms for obtaining predictions manually.
Behind the scene is the
Design function,
called by a modified version of
model.frame.default to
store extra attributes.
Design() is not intended to be
called by users.
Design
causes detailed design attributes
and descriptions of the distribution of predictors to be stored
in an attribute of the
terms component called
Design.
In addition to
model.frame.default being replaced by a modified
version,
[. and
[.factor are replaced by versions which carry
along the
label attribute of a variable. In this way, when an
na.action
function is called to subset out NAs, labels are still
defined for variables in the model.
Design(mf, allow.offset=TRUE, intercept=1) # not to be called by the user; called by fitting routines # dist <- datadist(x1,x2,sex,age,race,bp) # or dist <- datadist(my.data.frame) # Can omit call to datadist if not using summary.Design, plot.Design, # survplot.Design, or if all variable settings are given to them # options(datadist="dist") # f <- fitting.function(formula = y ~ rcs(x1,4) + rcs(x2,5) + x1%ia%x2 + # rcs(x1,4)%ia%rcs(x2,5) + # strat(sex)*age + strat(race)*bp) # See Design.trans for rcs, strat, etc. # %ia% is restricted interaction - not doubly nonlinear # for x1 by x2 this uses the simple product only, but pools x1*x2 # effect with nonlinear function for overall tests # specs(f) # anova(f) # summary(f) # fastbw(f) # pred <- predict(f, newdata=expand.grid(x1=1:10,x2=3,sex="male", # age=50,race="black")) # pred <- predict(f, newdata=gendata(f, x1=1:10, x2=3, sex="male")) # This leaves unspecified variables set to reference values from datadist # pred.combos <- gendata(f, nobs=10) # Use X-windows to edit predictor settings # predict(f, newdata=pred.combos) # plot(f, x1=NA) # latex(f) # nomogram(f)
TRUE if model fitter allows an
offset term
Frank Harrell
Department of Biostatistics, Vanderbilt University
f.harrell@vanderbilt.edu
## Not run:
library(Design, first=TRUE) # omit first for R
dist <- datadist(data=2) # can omit if not using summary, plot, survplot,
# or if specify all variable values to them. Can
# also defer. data=2: get distribution summaries
# for all variables in search position 2
# run datadist once, for all candidate variables
dist <- datadist(age,race,bp,sex,height) # alternative
options(datadist="dist")
f <- cph(Surv(d.time, death) ~ rcs(age,4)*strat(race) +
bp*strat(sex)+lsp(height,60),x=TRUE,y=TRUE)
anova(f)
anova(f,age,height) # Joint test of 2 vars
fastbw(f)
summary(f, sex="female") # Adjust sex to "female" when testing
# interacting factor bp
plot(f, age=NA, height=NA) # 3-D plot
plot(f, age=10:70, height=60)
latex(f) # LaTeX representation of fit
f <- lm(y ~ x) # Can use with any fitting function that
# calls model.frame.default, e.g. lm, glm
specs.Design(f) # Use .Design since class(f)="lm"
anova(f) # Works since Varcov(f) (=Varcov.lm(f)) works
fastbw(f)
options(datadist=NULL)
f <- ols(y ~ x1*x2) # Saves enough information to do fastbw, anova
anova(f) # Will not do plot.Design since distributions
fastbw(f) # of predictors not saved
plot(f, x1=seq(100,300,by=.5), x2=.5)
# all values defined - don't need datadist
dist <- datadist(x1,x2) # Equivalent to datadist(f)
options(datadist="dist")
plot(f, x1=NA, x2=.5) # Now you can do plot, summary
nomogram(f, interact=list(x2=c(.2,.7)))
## End(Not run)