grc(y, Rank = 1, Index.corner = 2:(1 + Rank),
szero = 1, summary.arg = FALSE, h.step = 1e-04, ...)
rcam(y, Rank = 0, family = poissonff, Musual = NULL,
Index.corner = if (!Rank) NULL else 1 + Musual * (1:Rank),
rprefix = "Row.", cprefix = "Col.",
szero = if (!Rank) NULL else {
if (Musual == 1) 1 else setdiff(1:(Musual * ncol(y)),
c(1 + (1:ncol(y)) * Musual, Index.corner))
},
summary.arg = FALSE, h.step = 0.0001,
rbaseline = 1, cbaseline = 1, ...)grc a matrix of counts.
For rcam a general matrix response depending on family.
Output from table() is acceptable; it is converted into a matrix.
Note that y must be at least 3 by min(nrow(y), ncol(y))}.
This is the dimension of the fit in terms of the interaction.
For grc() this argument must be positive.
A value of 0 means no interactions (i.e., main effects only);
Rank interaction term.
Not all family functions are suitable or make sense.
All other linear/additive predictorsRank integers.
These are used to store the Rank by Rank
identity matrix in the
A matrix; corner constraints are used.min(nrow(y), ncol(y))},
specifying the row that is used as the structural zero.TRUE, a summary is returned.
If TRUE, y may be the output (fitted
object) of grc().summary.rrvglm(). Only used when summary.arg = TRUE.rrvglm.control().family function
for an ordinary (univariate) response.
Then the number of linear predictors of the rcam() fit is
usually the number of columns of y multipl"grc", which currently is the same as
an "rrvglm" object.
Currently,
a rank-0 rcam() object is of class vglm-class,
but it may become of class "rcam" one day.rcam() is experimental at this stage and
may have some bugs.
Quite a lot of expertise is needed when fitting and in its
interpretion thereof. For example, the constraint
matrices applies the reduced-rank regression to the first linear
predictor and the other linear predictors are intercept-only and
have a common value throughout the entire data set.
This means that family = zipoissonff is
appropriate but not
family = zipoisson.
To understand what is going on, do examine the constraint
matrices of the fitted object, and reconcile this with Equations
(4.3) to (4.5) of Yee and Hastie (2003).
The functions temporarily create a permanent data frame
called .grc.df or .rcam.df, which used
to be needed by summary.rrvglm(). Then these
data frames are deleted before exiting the function.
If an error occurs, then the data frames may be present
in the workspace.
A %*% t(C),
the product of two `thin' matrices.
Indeed, A and C have Rank columns.
By default, the first column and row of the interaction matrix
A %*% t(C) is chosen
to be structural zeros, because szero = 1.
This means the first row of A are all zeros.
This function uses options()$contrasts to set up the row and
column indicator variables.
In particular, Equation (4.5) of Yee and Hastie (2003) is used.
These are called Row. and Col. (by default) followed
by the row or column number.
The function rcam() is more general than grc().
Its default is a no-interaction model of grc(), i.e.,
rank-0 and a Poisson distribution. This means that each
row and column has a dummy variable associated with it.
The first row and column is baseline.
The power of rcam() is that many family argument.
For example,
normal1 fits something in between a 2-way
ANOVA with and without interactions,
alaplace2 with Rank = 0 is something like
medpolish.
Others include
zipoissonff,
negbinomial.
Hopefully one day all family argument
although the result may not have meaning.
Goodman, L. A. (1981) Association models and canonical correlation in the analysis of cross-classifications having ordered categories. Journal of the American Statistical Association, 76, 320--334.
Documentation accompanying the
rrvglm,
rrvglm.control,
rrvglm-class,
summary.grc,
Rcam,
plotrcam0,
auuc,
olympic,
poissonff.# Some undergraduate student enrolments at the University of Auckland in 1990
grc1 <- grc(auuc)
fitted(grc1)
summary(grc1)
grc2 <- grc(auuc, Rank = 2, Index.corner = c(2, 5))
fitted(grc2)
summary(grc2)
# 2008 Summer Olympic Games in Beijing
top10 <- head(olympic, n = 10)
oly1 <- with(top10, grc(cbind(gold, silver, bronze)))
round(fitted(oly1))
round(resid(oly1, type = "response"), dig = 1) # Response residuals
summary(oly1)
Coef(oly1)
# Roughly median polish
rcam0 <- rcam(auuc, fam = alaplace2(tau = 0.5, intparloc = TRUE), trace = TRUE)
round(fitted(rcam0), dig = 0)
rcam0@y
round(coef(rcam0, matrix = TRUE), dig = 2)
print(Coef(rcam0, matrix = TRUE), dig = 3)
# constraints(rcam0)
names(constraints(rcam0))Run the code above in your browser using DataLab