Result Object from Constrained Ordination
Ordination methods cca
, rda
,
dbrda
and capscale
return similar result
objects. All these methods use the same internal function
ordConstrained
. They differ only in (1) initial
transformation of the data and in defining inertia, (2) weighting,
and (3) the use of rectangular rows x columns data or
symmetric rows x rows dissimilarities:
rda
initializes data to give variance or correlations
as inertia, cca
is based on double-standardized data
to give Chi-square inertia and uses row and column weights,
capscale
maps the real part of dissimilarities to
rectangular data and performs RDA, and dbrda
performs
an RDA-like analysis directly on symmetric dissimilarities.
Function ordConstrained
returns the same result components
for all these methods, and the calling function may add some more
components to the final result. However, you should not access these
result components directly (using $
): the internal structure
is not regarded as stable application interface (API), but it can
change at any release. If you access the results components
directly, you take a risk of breakage at any vegan release.
The vegan provides a wide set of accessor functions to those
components, and these functions are updated when the result object
changes. This documentation gives an overview of accessor functions
to the cca
result object.
ordiYbar(x, model = c("CCA", "CA", "pCCA", "partial", "initial")) ## S3 method for class 'cca' model.frame(formula, ...) ## S3 method for class 'cca' model.matrix(object, ...) ## S3 method for class 'cca' weights(object, display = "sites", ...)
object, x, formula |
|
model |
Show constrained ( |
display |
Display either |
... |
Other arguments passed to the the function. |
The internal (“working”) form of the dependent (community)
data can be accessed with function ordiYbar
. The form depends
on the ordination method: for instance, in cca
the
data are weighted and Chi-square transformed, and in
dbrda
they are Gower-centred dissimilarities. The
input data in the original (“response”) form can be accessed
with fitted.cca
and residuals.cca
.
Function predict.cca
can return either working or
response data, and also their lower-rank approximations.
The model matrix of independent data (“Constraints” and
“Conditions”) can be extracted with model.matrix
. In
partial analysis, the function returns a list of design matrices
called Conditions
and Constraints
. If either component
was missing, a single matrix is returned. The redundant (aliased)
terms do not appear in the model matrix. These terms can be found
with alias.cca
. Function model.frame
tries to
reconstruct the data frame from which the model matrices were
derived. This is only possible if the original model was fitted with
formula
and data
arguments, and still fails if the
data
are unavailable.
The number of observations can be accessed with
nobs.cca
, and the residual degrees of freedom with
df.residual.cca
. The information on observations with
missing values can be accessed with na.action
. The
terms and formula of the fitted model can be accessed with
formula
and terms
.
The ordination results are saved in separate components for partial terms, constraints and residual unconstrained ordination. There is no guarantee that these components will have the same internal names as currently, and you should be cautious when developing scripts and functions that directly access these components.
The constrained ordination algorithm is based on QR decomposition of
constraints and conditions (environmental data), and the QR
component is saved separately for partial and constrained
components. The QR decomposition of constraints can be accessed
with qr.cca
. This will also include the residual
effects of partial terms (Conditions), and it should be used
together with ordiYbar(x, "partial")
. The environmental data
are first centred in rda
or weighted and centred in
cca
. The QR decomposition is used in many functions that
access cca
results, and it can be used to find many items
that are not directly stored in the object. For examples, see
coef.cca
, coef.rda
,
vif.cca
, permutest.cca
,
predict.cca
, predict.rda
,
calibrate.cca
. See qr
for other possible
uses of this component. For instance, the rank of the constraints
can be found from the QR decomposition.
The eigenvalues of the solution can be accessed with
eigenvals.cca
. Eigenvalues are not evaluated for
partial component, and they will only be available for constrained
and residual components.
The ordination scores are internally stored as (weighted)
orthonormal scores matrices. These results can be accessed with
scores.cca
and scores.rda
functions. The
ordination scores are scaled when accessed with scores
functions, but internal (weighted) orthonormal scores can be
accessed by setting scaling = FALSE
. Unconstrained residual
component has species and site scores, and constrained component has
also fitted site scores or linear combination scores for sites and
biplot scores and centroids for constraint variables. The biplot
scores correspond to the model.matrix
, and centroids
are calculated for factor variables when they were used. The scores
can be selected by defining the axes, and there is no direct way of
accessing all scores of a certain component. The number of dimensions
can be assessed from eigenvals
. In addition, some
other types can be derived from the results although not saved in
the results. For instance, regression scores and model coefficients
can be accessed with scores
and coef
functions. Partial component will have no scores.
Distance-based methods (dbrda
, capscale
)
can have negative eigenvalues and associated imaginary axis
scores. There is no way of accessing these imaginary scores. In
addition, species scores are initially missing in
dbrda
and they are accessory and found after analysis
in capscale
(and may be misleading). Function
sppscores
can be used to add species scores or replace
them with more meaningful ones.
Saving of “working” dependent (community) data changed in
vegan version 2.5-0, and you should use ordiYbar
function instead of direct access, or your scripts and functions
will fail (ordiYbar
has been available since vegan
version 2.4-3, and it works both with the old and current result
objects).
The model.matrix
returns the unweighted model matrix also for
cca
. Prior to vegan version 2.5-0 it returned
the weighted model matrix
Jari Oksanen
Legendre, P. and Legendre, L. (2012) Numerical Ecology. 3rd English ed. Elsevier.
The core function is ordConstrained
which is called by
cca
, rda
, dbrda
and
capscale
. The basic class is "cca"
for all
methods, and the following functions are defined for this class:
RsquareAdj.cca
, SSD.cca
, add1.cca
, alias.cca
, anova.cca
, as.mlm.cca
, biplot.cca
, bstick.cca
, calibrate.cca
, coef.cca
, cooks.distance.cca
, deviance.cca
, df.residual.cca
, drop1.cca
, eigenvals.cca
, extractAIC.cca
, fitted.cca
, goodness.cca
, hatvalues.cca
, labels.cca
, model.frame.cca
, model.matrix.cca
, nobs.cca
, permutest.cca
, plot.cca
, points.cca
, predict.cca
, print.cca
, qr.cca
, residuals.cca
, rstandard.cca
, rstudent.cca
, scores.cca
, screeplot.cca
, sigma.cca
, simulate.cca
, stressplot.cca
, summary.cca
, text.cca
, tolerance.cca
, vcov.cca
, weights.cca
.
Other functions handling "cca"
objects include inertcomp
,
intersetcor
, mso
, ordiresids
,
ordistep
and ordiR2step
.
Please choose more modern alternatives, such as Google Chrome or Mozilla Firefox.