R/methods_mlm.R
model_parameters.mlm.RdParameters from multinomial or cumulative link models
# S3 method for class 'mlm'
model_parameters(
model,
ci = 0.95,
vcov = NULL,
vcov_args = NULL,
bootstrap = FALSE,
iterations = 1000,
standardize = NULL,
exponentiate = FALSE,
p_adjust = NULL,
keep = NULL,
drop = NULL,
verbose = TRUE,
...
)A model with multinomial or categorical response value.
Confidence Interval (CI) level. Default to 0.95 (95%).
Variance-covariance matrix used to compute uncertainty estimates (e.g., for robust standard errors). This argument accepts a covariance matrix, a function which returns a covariance matrix, or a string which identifies the function to be used to compute the covariance matrix.
A covariance matrix
A function which returns a covariance matrix (e.g., stats::vcov())
A string which indicates the kind of uncertainty estimates to return.
Heteroskedasticity-consistent: "HC", "HC0", "HC1", "HC2",
"HC3", "HC4", "HC4m", "HC5". See ?sandwich::vcovHC
Cluster-robust: "CR", "CR0", "CR1", "CR1p", "CR1S",
"CR2", "CR3". See ?clubSandwich::vcovCR
Bootstrap: "BS", "xy", "residual", "wild", "mammen",
"fractional", "jackknife", "norm", "webb". See
?sandwich::vcovBS
Other sandwich package functions: "HAC", "PC", "CL", "OPG",
"PL".
List of arguments to be passed to the function identified by
the vcov argument. This function is typically supplied by the
sandwich or clubSandwich packages. Please refer to their
documentation (e.g., ?sandwich::vcovHAC) to see the list of available
arguments. If no estimation type (argument type) is given, the default
type for "HC" equals the default from the sandwich package; for type
"CR", the default is set to "CR3".
Should estimates be based on bootstrapped model? If TRUE,
then arguments of Bayesian regressions apply
(see also bootstrap_parameters()).
The number of bootstrap replicates. This only apply in the case of bootstrapped frequentist models.
The method used for standardizing the parameters. Can be
NULL (default; no standardization), "refit" (for re-fitting the model
on standardized data) or one of "basic", "posthoc", "smart",
"pseudo". See 'Details' in standardize_parameters().
Importantly:
The "refit" method does not standardize categorical predictors (i.e.
factors), which may be a different behaviour compared to other R packages
(such as lm.beta) or other software packages (like SPSS). to mimic
such behaviours, either use standardize="basic" or standardize the data
with datawizard::standardize(force=TRUE) before fitting the model.
By default, the response (dependent) variable is also standardized, if
applicable. Set include_response = FALSE to avoid standardization of
the response variable. See details in datawizard::standardize.default().
For mixed models, when using methods other than "refit", only the fixed
effects will be standardized.
Robust estimation (i.e., vcov set to a value other than NULL) of
standardized parameters only works when standardize="refit".
Logical, indicating whether or not to exponentiate the
coefficients (and related confidence intervals). This is typical for
logistic regression, or more generally speaking, for models with log or
logit links. It is also recommended to use exponentiate = TRUE for models
with log-transformed response values. For models with a log-transformed
response variable, when exponentiate = TRUE, a one-unit increase in the
predictor is associated with multiplying the outcome by that predictor's
coefficient. Note: Delta-method standard errors are also computed (by
multiplying the standard errors by the transformed coefficients). This is
to mimic behaviour of other software packages, such as Stata, but these
standard errors poorly estimate uncertainty for the transformed
coefficient. The transformed confidence interval more clearly captures this
uncertainty. For compare_parameters(), exponentiate = "nongaussian"
will only exponentiate coefficients from non-Gaussian families.
String value, if not NULL, indicates the method to adjust
p-values. See stats::p.adjust() for details. Further possible
adjustment methods are "tukey", "scheffe", "sidak", "sup-t", and
"none" to explicitly disable adjustment for emmGrid objects (from
emmeans). "sup-t" computes simultaneous confidence bands, also called
sup-t confidence band (Montiel Olea & Plagborg-Møller, 2019).
Character containing a regular expression pattern that
describes the parameters that should be included (for keep) or excluded
(for drop) in the returned data frame. keep may also be a
named list of regular expressions. All non-matching parameters will be
removed from the output. If keep is a character vector, every parameter
name in the "Parameter" column that matches the regular expression in
keep will be selected from the returned data frame (and vice versa,
all parameter names matching drop will be excluded). Furthermore, if
keep has more than one element, these will be merged with an OR
operator into a regular expression pattern like this: "(one|two|three)".
If keep is a named list of regular expression patterns, the names of the
list-element should equal the column name where selection should be
applied. This is useful for model objects where model_parameters()
returns multiple columns with parameter components, like in
model_parameters.lavaan(). Note that the regular expression pattern
should match the parameter names as they are stored in the returned data
frame, which can be different from how they are printed. Inspect the
$Parameter column of the parameters table to get the exact parameter
names.
See keep.
Toggle warnings and messages.
Arguments passed to or from other methods. For instance, when
bootstrap = TRUE, arguments like type or parallel are passed down to
bootstrap_model().
Further non-documented arguments are:
digits, p_digits, ci_digits and footer_digits to set the number of
digits for the output. groups can be used to group coefficients. These
arguments will be passed to the print-method, or can directly be used in
print(), see documentation in print.parameters_model().
If s_value = TRUE, the p-value will be replaced by the S-value in the
output (cf. Rafi and Greenland 2020).
pd adds an additional column with the probability of direction (see
bayestestR::p_direction() for details). Furthermore, see 'Examples' for
this function.
For developers, whose interest mainly is to get a "tidy" data frame of
model summaries, it is recommended to set pretty_names = FALSE to speed
up computation of the summary table.
A data frame of indices related to the model's parameters.
Multinomial or cumulative link models, i.e. models where the
response value (dependent variable) is categorical and has more than two
levels, usually return coefficients for each response level. Hence, the
output from model_parameters() will split the coefficient tables
by the different levels of the model's response.
Possible values for the component argument depend on the model class.
Following are valid options:
"all": returns all model components, applies to all models, but will only
have an effect for models with more than just the conditional model component.
"conditional": only returns the conditional component, i.e. "fixed effects"
terms from the model. Will only have an effect for models with more than
just the conditional model component.
"smooth_terms": returns smooth terms, only applies to GAMs (or similar
models that may contain smooth terms).
"zero_inflated" (or "zi"): returns the zero-inflation component.
"dispersion": returns the dispersion model component. This is common
for models with zero-inflation or that can model the dispersion parameter.
"instruments": for instrumental-variable or some fixed effects regression,
returns the instruments.
"nonlinear": for non-linear models (like models of class nlmerMod or
nls), returns staring estimates for the nonlinear parameters.
"correlation": for models with correlation-component, like gls, the
variables used to describe the correlation structure are returned.
Special models
Some model classes also allow rather uncommon options. These are:
mhurdle: "infrequent_purchase", "ip", and "auxiliary"
BGGM: "correlation" and "intercept"
BFBayesFactor, glmx: "extra"
averaging:"conditional" and "full"
mjoint: "survival"
mfx: "precision", "marginal"
betareg, DirichletRegModel: "precision"
mvord: "thresholds" and "correlation"
clm2: "scale"
selection: "selection", "outcome", and "auxiliary"
lavaan: One or more of "regression", "correlation", "loading",
"variance", "defined", or "mean". Can also be "all" to include
all components.
For models of class brmsfit (package brms), even more options are
possible for the component argument, which are not all documented in detail
here.
insight::standardize_names() to rename
columns into a consistent, standardized naming scheme.
data("stemcell", package = "brglm2")
model <- brglm2::bracl(
research ~ as.numeric(religion) + gender,
weights = frequency,
data = stemcell,
type = "ML"
)
model_parameters(model)
#> # Response level: definitely
#>
#> Parameter | Log-Odds | SE | 95% CI | z | p
#> -------------------------------------------------------------------
#> (Intercept) | -1.25 | 0.26 | [-1.76, -0.73] | -4.76 | < .001
#> religion | 0.44 | 0.10 | [ 0.23, 0.64] | 4.20 | < .001
#> gender [female] | -0.14 | 0.17 | [-0.47, 0.19] | -0.82 | 0.414
#>
#> # Response level: probably
#>
#> Parameter | Log-Odds | SE | 95% CI | z | p
#> ----------------------------------------------------------------
#> (Intercept) | 0.47 | 0.29 | [-0.10, 1.04] | 1.62 | 0.105
#> religion | 0.26 | 0.13 | [ 0.01, 0.51] | 2.01 | 0.044
#> gender [female] | 0.19 | 0.21 | [-0.22, 0.60] | 0.90 | 0.370
#>
#> # Response level: probably not
#>
#> Parameter | Log-Odds | SE | 95% CI | z | p
#> -----------------------------------------------------------------
#> (Intercept) | 0.43 | 0.39 | [-0.33, 1.18] | 1.11 | 0.268
#> religion | 0.01 | 0.17 | [-0.33, 0.35] | 0.07 | 0.945
#> gender [female] | -0.16 | 0.28 | [-0.71, 0.39] | -0.57 | 0.566
#>
#> Uncertainty intervals (equal-tailed) and p-values (two-tailed) computed
#> using a Wald z-distribution approximation.