demean | R Documentation |
demean()
computes group- and de-meaned versions of a variable that can be
used in regression analysis to model the between- and within-subject effect.
degroup()
is more generic in terms of the centering-operation. While
demean()
always uses mean-centering, degroup()
can also use the mode or
median for centering.
demean(
x,
select,
by,
nested = FALSE,
suffix_demean = "_within",
suffix_groupmean = "_between",
add_attributes = TRUE,
verbose = TRUE
)
degroup(
x,
select,
by,
nested = FALSE,
center = "mean",
suffix_demean = "_within",
suffix_groupmean = "_between",
add_attributes = TRUE,
verbose = TRUE
)
detrend(
x,
select,
by,
nested = FALSE,
center = "mean",
suffix_demean = "_within",
suffix_groupmean = "_between",
add_attributes = TRUE,
verbose = TRUE
)
x |
A data frame. |
select |
Character vector (or formula) with names of variables to select that should be group- and de-meaned. |
by |
Character vector (or formula) with the name of the variable that
indicates the group- or cluster-ID. For cross-classified or nested designs,
For nested designs,
See also section De-meaning for cross-classified designs and De-meaning for nested designs below. |
nested |
Logical, if |
suffix_demean , suffix_groupmean |
String value, will be appended to the
names of the group-meaned and de-meaned variables of |
add_attributes |
Logical, if |
verbose |
Toggle warnings and messages. |
center |
Method for centering. |
A data frame with the group-/de-meaned variables, which get the suffix
"_between"
(for the group-meaned variable) and "_within"
(for the
de-meaned variable) by default. For cross-classified or nested designs,
the name pattern of the group-meaned variables is the name of the centered
variable followed by the name of the variable that indicates the related
grouping level, e.g. predictor_L3_between
and predictor_L2_between
.
Mixed models include different levels of sources of variability, i.e. error terms at each level. When macro-indicators (or level-2 predictors, or higher-level units, or more general: group-level predictors that vary within and across groups) are included as fixed effects (i.e. treated as covariate at level-1), the variance that is left unaccounted for this covariate will be absorbed into the error terms of level-1 and level-2 (Bafumi and Gelman 2006; Gelman and Hill 2007, Chapter 12.6.): "Such covariates contain two parts: one that is specific to the higher-level entity that does not vary between occasions, and one that represents the difference between occasions, within higher-level entities" (Bell et al. 2015). Hence, the error terms will be correlated with the covariate, which violates one of the assumptions of mixed models (iid, independent and identically distributed error terms). This bias is also called the heterogeneity bias (Bell et al. 2015). To resolve this problem, level-2 predictors used as (level-1) covariates should be separated into their "within" and "between" effects by "de-meaning" and "group-meaning": After demeaning time-varying predictors, "at the higher level, the mean term is no longer constrained by Level 1 effects, so it is free to account for all the higher-level variance associated with that variable" (Bell et al. 2015).
demean()
is intended to create group- and de-meaned variables for panel
regression models (fixed effects models), or for complex
random-effect-within-between models (see Bell et al. 2015, 2018), where
group-effects (random effects) and fixed effects correlate (see
Bafumi and Gelman 2006). This can happen, for instance, when analyzing
panel data, which can lead to Heterogeneity Bias. To control for correlating
predictors and group effects, it is recommended to include the group-meaned
and de-meaned version of time-varying covariates (and group-meaned version
of time-invariant covariates that are on a higher level, e.g. level-2
predictors) in the model. By this, one can fit complex multilevel models for
panel data, including time-varying predictors, time-invariant predictors and
random effects.
A mixed models approach can model the causes of endogeneity explicitly by including the (separated) within- and between-effects of time-varying fixed effects and including time-constant fixed effects. Furthermore, mixed models also include random effects, thus a mixed models approach is superior to classic fixed-effects models, which lack information of variation in the group-effects or between-subject effects. Furthermore, fixed effects regression cannot include random slopes, which means that fixed effects regressions are neglecting "cross-cluster differences in the effects of lower-level controls (which) reduces the precision of estimated context effects, resulting in unnecessarily wide confidence intervals and low statistical power" (Heisig et al. 2017).
The group-meaned variable is simply the mean of an independent variable
within each group (or id-level or cluster) represented by by
. It represents
the cluster-mean of an independent variable. The regression coefficient of a
group-meaned variable is the between-subject-effect. The de-meaned variable
is then the centered version of the group-meaned variable. De-meaning is
sometimes also called person-mean centering or centering within clusters.
The regression coefficient of a de-meaned variable represents the
within-subject-effect.
For continuous time-varying predictors, the recommendation is to include both their de-meaned and group-meaned versions as fixed effects, but not the raw (untransformed) time-varying predictors themselves. The de-meaned predictor should also be included as random effect (random slope). In regression models, the coefficient of the de-meaned predictors indicates the within-subject effect, while the coefficient of the group-meaned predictor indicates the between-subject effect.
For binary time-varying predictors, there are two recommendations. First
is to include the raw (untransformed) binary predictor as fixed effect
only and the de-meaned variable as random effect (random slope).
The alternative would be to add the de-meaned version(s) of binary
time-varying covariates as additional fixed effect as well (instead of
adding it as random slope). Centering time-varying binary variables to
obtain within-effects (level 1) isn't necessary. They have a sensible
interpretation when left in the typical 0/1 format (Hoffmann 2015,
chapter 8-2.I). demean()
will thus coerce categorical time-varying
predictors to numeric to compute the de- and group-meaned versions for
these variables, where the raw (untransformed) binary predictor and the
de-meaned version should be added to the model.
Factors with more than two levels are demeaned in two ways: first, these are also converted to numeric and de-meaned; second, dummy variables are created (binary, with 0/1 coding for each level) and these binary dummy-variables are de-meaned in the same way (as described above). Packages like panelr internally convert factors to dummies before demeaning, so this behaviour can be mimicked here.
There are multiple ways to deal with interaction terms of within- and between-effects.
A classical approach is to simply use the product term of the de-meaned
variables (i.e. introducing the de-meaned variables as interaction term
in the model formula, e.g. y ~ x_within * time_within
). This approach,
however, might be subject to bias (see Giesselmann & Schmidt-Catran 2020).
Another option is to first calculate the product term and then apply the
de-meaning to it. This approach produces an estimator "that reflects
unit-level differences of interacted variables whose moderators vary
within units", which is desirable if no within interaction of
two time-dependent variables is required. This is what demean()
does
internally when select
contains interaction terms.
A third option, when the interaction should result in a genuine within
estimator, is to "double de-mean" the interaction terms
(Giesselmann & Schmidt-Catran 2018), however, this is currently
not supported by demean()
. If this is required, the wmb()
function from the panelr package should be used.
To de-mean interaction terms for within-between models, simply specify
the term as interaction for the select
-argument, e.g. select = "a*b"
(see 'Examples').
demean()
can handle cross-classified designs, where the data has two or
more groups at the higher (i.e. second) level. In such cases, the
by
-argument can identify two or more variables that represent the
cross-classified group- or cluster-IDs. The de-meaned variables for
cross-classified designs are simply subtracting all group means from each
individual value, i.e. fully cluster-mean-centering (see Guo et al. 2024
for details). Note that de-meaning for cross-classified designs is not
equivalent to de-meaning of nested data structures from models with three or
more levels. Set nested = TRUE
to explicitly assume a nested design. For
cross-classified designs, de-meaning is supposed to work for models like
y ~ x + (1|level3) + (1|level2)
, but not for models like
y ~ x + (1|level3/level2)
. Note that demean()
and degroup()
can't
handle a mix of nested and cross-classified designs in one model.
Brincks et al. (2017) have suggested an algorithm to center variables for
nested designs, which is implemented in demean()
. For nested designs, set
nested = TRUE
and specify the variables that indicate the different
levels in descending order in the by
argument. E.g.,
by = c("level4", "level3, "level2")
assumes a model like
y ~ x + (1|level4/level3/level2)
. An alternative notation for the
by
-argument would be by = "level4/level3/level2"
, similar to the
formula notation.
A description of how to translate the formulas described in Bell et al. 2018
into R using lmer()
from lme4 can be found in
this vignette.
Bafumi J, Gelman A. 2006. Fitting Multilevel Models When Predictors and Group Effects Correlate. In. Philadelphia, PA: Annual meeting of the American Political Science Association.
Bell A, Fairbrother M, Jones K. 2019. Fixed and Random Effects Models: Making an Informed Choice. Quality & Quantity (53); 1051-1074
Bell A, Jones K. 2015. Explaining Fixed Effects: Random Effects Modeling of Time-Series Cross-Sectional and Panel Data. Political Science Research and Methods, 3(1), 133–153.
Brincks, A. M., Enders, C. K., Llabre, M. M., Bulotsky-Shearer, R. J., Prado, G., and Feaster, D. J. (2017). Centering Predictor Variables in Three-Level Contextual Models. Multivariate Behavioral Research, 52(2), 149–163. https://doi.org/10.1080/00273171.2016.1256753
Gelman A, Hill J. 2007. Data Analysis Using Regression and Multilevel/Hierarchical Models. Analytical Methods for Social Research. Cambridge, New York: Cambridge University Press
Giesselmann M, Schmidt-Catran, AW. 2020. Interactions in fixed effects regression models. Sociological Methods & Research, 1–28. https://doi.org/10.1177/0049124120914934
Guo Y, Dhaliwal J, Rights JD. 2024. Disaggregating level-specific effects in cross-classified multilevel models. Behavior Research Methods, 56(4), 3023–3057.
Heisig JP, Schaeffer M, Giesecke J. 2017. The Costs of Simplicity: Why Multilevel Models May Benefit from Accounting for Cross-Cluster Differences in the Effects of Controls. American Sociological Review 82 (4): 796–827.
Hoffman L. 2015. Longitudinal analysis: modeling within-person fluctuation and change. New York: Routledge
If grand-mean centering (instead of centering within-clusters)
is required, see center()
. See performance::check_heterogeneity_bias()
to check for heterogeneity bias.
data(iris)
iris$ID <- sample(1:4, nrow(iris), replace = TRUE) # fake-ID
iris$binary <- as.factor(rbinom(150, 1, .35)) # binary variable
x <- demean(iris, select = c("Sepal.Length", "Petal.Length"), by = "ID")
head(x)
x <- demean(iris, select = c("Sepal.Length", "binary", "Species"), by = "ID")
head(x)
# demean interaction term x*y
dat <- data.frame(
a = c(1, 2, 3, 4, 1, 2, 3, 4),
x = c(4, 3, 3, 4, 1, 2, 1, 2),
y = c(1, 2, 1, 2, 4, 3, 2, 1),
ID = c(1, 2, 3, 1, 2, 3, 1, 2)
)
demean(dat, select = c("a", "x*y"), by = "ID")
# or in formula-notation
demean(dat, select = ~ a + x * y, by = ~ID)
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