cobalt
?Most questions below are related to this one, so here I will try to explain in complete detail how standardized mean differences (SMDs) are computed.
First, it is important to know that by default, mean
differences for binary covariates are not standardized. That
means in the Diff.Adj
column, etc., what you are seeing the
is raw difference in proportion for binary variables. (By raw,
I mean unstandardized, but weights may be applied if relevant.) To
request SMDs for binary covariates, set binary = "std"
in
the call to bal.tab()
or love.plot()
. See also
the question below.
For continuous covariates, the standardized mean difference is computed as $$ \text{SMD} = \frac{\bar{x}_1 - \bar{x}_0}{s^*} $$ where x̄1 is the mean of the covariate in the treated group, x̄0 is the mean of the covariate in the control group, and s* is a standardization factor (not necessarily a standard deviation!). After matching or weighting, the weighted standardized mean difference is computed as $$ \text{SMD}^w = \frac{\bar{x}_{1w} - \bar{x}_{0w}}{s^*} $$ where x̄1w is the weighted mean of the covariate in the treated group, i.e., $\bar{x}_{1w} = \frac{1}{\sum_{i:A_i = 1}{w_i}}\sum_{i:A_i=1}{w_ix_i}$, and similarly for the control group. Critically, the standardization factor s* is the same before and after weighting. I will repeat, the standardization factor s* is the same before and after weighting. I don’t mean it has the same formula, it mean it is literally the same value. I explain in more detail in a question below why this is the case.
How is the standardization factor computed? This depends on the
argument to s.d.denom
supplied to bal.tab()
or
love.plot()
. When s.d.denom
is not supplied,
this is determined by the argument supplied to estimand
,
and when that is not supplied, the estimand is guess based on the form
of the weights, if any. By default, with no weights supplied and no
argument to s.d.denom
or estimand
,
s.d.denom
is set to "pooled"
, and a note will
appear saying so. That note doesn’t appear if weights are supplied or
balance is assessed on the output of a another package, as the estimand,
and therefore s.d.denom
, can be determined
automatically.
Below are the formulas for the standardization factor corresponding
to each value of s.d.denom
:
"pooled"
: $s^* =
\sqrt{\frac{s_1^2 + s_0^2}{2}}$"treated"
: s* = s1"control"
: s* = s0"all"
: s* = s"weighted"
: s* = sw"hedges"
: $s^* = \frac{1}{1 -
\frac{3}{4(n - 2) - 1}}\sqrt{\frac{(n_1 - 1)s_1^2 + (n_0 - 1)s_0^2}{n -
2}}$where s1 is the standard deviation of the treated group, s0 is the standard deviation of the control group, s is the standard deviation of the whole sample ignoring treatment group membership, sw is the weighted standard deviation of the whole sample, n1 and n0 are sizes of the treated and control groups, respectively, and n = n1 + n0.1 For continuous covariates, the unweighted standard deviation is computed as usual, i.e., as $$ s = \sqrt{\frac{1}{n-1}\sum_i{(x_i - \bar{x})^2}} $$ and the weighted standard deviation is computed as $$ s = \sqrt{\frac{\sum_{i} w_{i}}{(\sum_{i} w_{i})^2 - \sum_{i=1}^{n} w^2_{i}}\sum_i{w_i(x_i - \bar{x}_w)^2}} $$For binary covariates, the unweighted standard deviation is computed as $s = \sqrt{\bar{x}(1-\bar{x})}$ and the weighted standard deviation is computed as $s = \sqrt{\bar{x}_w(1-\bar{x}_w)}$.
When sampling weights are supplied, all standard deviations in the
standardization factor are computed incorporating the sampling weights.
When s.d.denom = "weighted"
, the standardization factor is
computed using the weights used to balance the sample (i.e., the
matching or weighting weights), even for the unadjusted sample.
Remember, the standardization is ALWAYS the same before and after
adjustment.
I know some of these formulas seem overly complicated for such simple statistics, but they are required to keep things consistent and not dependent on the scale of the weights.
Ultimately, bias in the treatment effect estimate is a function of imbalance. That bias is indifferent to whether you measure that imbalance using a standardized or unstandardized mean difference. The reason we use SMDs is that covariates naturally are on a variety of different scales, and when trying to quickly assess whether a sample is balanced, it is productive to unify the scales of the covariates. That way, balance on a covariate measured with large numbers (e.g., days in hospital or prior earnings in dollars) can be assessed alongside balance on a covariate measured with small numbers (e.g., number of comorbidities or years of education).
With binary covariates, though, they are already on a comprehensible scale, so there is no need to standardize. In addition, the scale is intuitive for people; a difference in proportion of .1 when both groups have 100 people means that there is an imbalance of 10 people on the covariate. Are 10 people being different enough to cause bias in the estimate? That can be assessed substantively without needing to take the additional step of translating the variable’s scale into something meaningful.
Another important reason why mean difference are not standardized is
that it is possible for two covariates with the same imbalance to have
vastly different mean differences. For example, consider the following
dataset. X1
and X2
both have a mean difference
of .1; if they both affected the outcome equally, then each would
contribute to the bias in the estimate to the same extent.
treat <- rep(1:0, each = 20)
X1 <- c(rep(0:1, c(1, 19)), rep(0:1, c(3, 17)))
X2 <- c(rep(0:1, c(9, 11)), rep(0:1, c(11, 9)))
bal.tab(treat ~ X1 + X2,
binary = "raw",
disp = "means",
s.d.denom = "treated")
#> Balance Measures
#> Type M.0.Un M.1.Un Diff.Un
#> X1 Binary 0.85 0.95 0.1
#> X2 Binary 0.45 0.55 0.1
#>
#> Sample sizes
#> Control Treated
#> All 20 20
But if we standardized the mean differences, not only do we move away
from an actually interpretable statistic (i.e., what does it mean to
divide by the standard deviation of a binary variable?), we see that the
standardized mean difference vary by a huge amount, with X1
having twice the imbalance of X2
.
bal.tab(treat ~ X1 + X2,
binary = "std",
s.d.denom = "treated")
#> Balance Measures
#> Type Diff.Un
#> X1 Binary 0.4588
#> X2 Binary 0.2010
#>
#> Sample sizes
#> Control Treated
#> All 20 20
Why does this happen? The standard deviation of a binary variable is a function of its mean (in particular, it is $s = \sqrt{p(1-p)}$) where p is the mean of the variable). That means information about the mean of the variable, which is unrelated to imbalance, contaminates the standardized mean difference, which is supposed to measure imbalance. In this case, standardizing the mean difference only adds confusion and reduces interpretability. That is why, by default, mean differences for binary variables are unstandardized by default.
You can always change this by setting binary = "std"
in
the call to bal.tab()
or setting
set.cobalt.options(binary = "std")
to change the option for
the whole session. One advantage of using standardized mean differences
for binary variables is that they are always larger than the raw mean
difference (because the standardization factor is always less than 1),
which means if you use the standardized mean difference as your balance
criterion, you will always seek better balance than using the raw mean
differences. The balance statistics computed by
bal.compute()
that involve the standardized mean difference
standardize all variables, including binary variables.
It is important to remember that bias is a function of the difference in means of a covariate and standardization is a tool to aid in balance assessment. As a tool, it should reflect imbalance accurately (i.e., without incorporating extraneous information), but there is no statistical “truth” about the nature of the standardization factor. I use the same standardization factor before and after adjustment as recommended by Stuart (2008). The rationale is that by isolating the SMD to reflect changes in the difference in means, why can more accurately assess improvement in balance rather than combining information about the difference in means with information about the variability of the covariate, which may change in a variety of ways after adjustment. I describe a specific example of how allowing the standardization factor to change can cause problems here.
bal.tab()
object?The output of a call to bal.tab()
is a
bal.tab
object, which has several components depending on
the features of the dataset (e.g., whether the data are multiply imputed
or clustered or whether the treatment is binary or multi-category,
etc.). In the most basic case, a binary or continuous treatment with no
clustering, no multiple imputations, a single time point, and
subclassification is not used, the balance table is stored in the
Balance
component of the output object. Let’s take a
look:
data("lalonde")
b <- bal.tab(treat ~ age + educ + race + married + re74,
data = lalonde, s.d.denom = "treated",
disp = "means", stats = c("m", "v"))
# View the structure of the object
str(b, give.attr = FALSE)
#> List of 2
#> $ Balance :'data.frame': 7 obs. of 9 variables:
#> ..$ Type : chr [1:7] "Contin." "Contin." "Binary" "Binary" ...
#> ..$ M.0.Un : num [1:7] 28.03 10.235 0.203 0.142 0.655 ...
#> ..$ M.1.Un : num [1:7] 25.8162 10.3459 0.8432 0.0595 0.0973 ...
#> ..$ Diff.Un : num [1:7] -0.3094 0.055 0.6404 -0.0827 -0.5577 ...
#> ..$ V.Ratio.Un : num [1:7] 0.44 0.496 NA NA NA ...
#> ..$ M.0.Adj : num [1:7] NA NA NA NA NA NA NA
#> ..$ M.1.Adj : num [1:7] NA NA NA NA NA NA NA
#> ..$ Diff.Adj : num [1:7] NA NA NA NA NA NA NA
#> ..$ V.Ratio.Adj: num [1:7] NA NA NA NA NA NA NA
#> $ Observations:'data.frame': 1 obs. of 2 variables:
#> ..$ Control: num 429
#> ..$ Treated: num 185
b$Balance
#> Type M.0.Un M.1.Un Diff.Un V.Ratio.Un M.0.Adj
#> age Contin. 28.0303030 2.581622e+01 -0.30944526 0.4399955 NA
#> educ Contin. 10.2354312 1.034595e+01 0.05496466 0.4958934 NA
#> race_black Binary 0.2027972 8.432432e-01 0.64044604 NA NA
#> race_hispan Binary 0.1421911 5.945946e-02 -0.08273168 NA NA
#> race_white Binary 0.6550117 9.729730e-02 -0.55771436 NA NA
#> married Binary 0.5128205 1.891892e-01 -0.32363132 NA NA
#> re74 Contin. 5619.2365064 2.095574e+03 -0.72108381 0.5181285 NA
#> M.1.Adj Diff.Adj V.Ratio.Adj
#> age NA NA NA
#> educ NA NA NA
#> race_black NA NA NA
#> race_hispan NA NA NA
#> race_white NA NA NA
#> married NA NA NA
#> re74 NA NA NA
It’s not a very pretty object, which is why the print()
method makes it look nicer. If you are willing to process this table
yourself, you can easily extract it from the bal.tab()
output and do what you want with it, e.g., saving it to a CSV file or
making a pretty table using another package. Although I have been
working on a way to do this more easily (i.e., to create a
publication-ready table from a bal.tab
object), it might be
a while because the main purpose of this package is balance assessment,
not formatting for publication (although I did put a lot of work into
love.plot()
to make it customizable for publication).
Subclassification involves creating strata (usually based on the
propensity score), within which covariates are ideally balanced.
bal.tab()
lets you assess balance both within and across
subclasses.
One must always remember that the standardized mean difference uses
the standardization factor computed in the original sample, i.e., prior
to subclassification. Let’s take a look below using
MatchIt
:
# PS Subclassification
msub <- MatchIt::matchit(treat ~ age + educ + race + married + re74,
data = lalonde, method = "subclass",
estimand = "ATE", min.n = 4)
# Balance in the first subclass
bal.tab(msub, which.sub = 1, binary = "std")
#> Balance by subclass
#> - - - Subclass 1 - - -
#> Type Diff.Adj
#> distance Distance 0.1574
#> age Contin. -1.0433
#> educ Contin. -0.2759
#> race_black Binary 0.0000
#> race_hispan Binary 0.0000
#> race_white Binary 0.0000
#> married Binary -1.1135
#> re74 Contin. -1.8353
Let’s see where the number -1.0433
came from (the
standardized mean difference for age
). We compute the mean
of age
in each treatment group in subclass 1, and then
divide it by the pooled standard deviation of age (because we requested
the ATE) in the original sample.
m0 <- mean(lalonde$age[lalonde$treat == 0 & msub$subclass == 1])
m1 <- mean(lalonde$age[lalonde$treat == 1 & msub$subclass == 1])
s0 <- sd(lalonde$age[lalonde$treat == 0])
s1 <- sd(lalonde$age[lalonde$treat == 1])
(m1 - m0) / sqrt((s1^2 + s0^2) / 2)
#> [1] -1.043294
A common mistake is to compute the standard deviation within each subclass. There are a few reasons why this is bad: 1) it suffers from the same problem that changing the standardization factor does with matching or weighting, i.e., that balance can appear to be worse because the standardization factor shrank even as the means got closer together; 2) when there is no or little variation of a covariate within a subclass, which is desirable, the standardization factor will be tiny, making the SMD potentially appear huge; and 3) the same variable will use different standardization factors across subclasses, which means the same difference in means, which contribute to bias equally, will have different balance statistics.
A related question is how the balance statistics are computed across
subclasses to compute an overall balance statistic for the sample. For
(standardized) mean differences, it is as easy as computing the average
of the statistic across subclasses, where the statistics are weighted
corresponding to the number of units in the subclass in the target group
(e.g., the treated units for the ATT, all units for the ATE, etc.).
Below I’ll demonstrate how to do that manually for the age
covariate:
# SMDs across subclasses for age
smds <- sapply(1:6, function(s) {
m0 <- mean(lalonde$age[lalonde$treat == 0 & msub$subclass == s])
m1 <- mean(lalonde$age[lalonde$treat == 1 & msub$subclass == s])
s0 <- sd(lalonde$age[lalonde$treat == 0])
s1 <- sd(lalonde$age[lalonde$treat == 1])
(m1 - m0) / sqrt((s1^2 + s0^2) / 2)
})
# Sample size in each subclass
ns <- table(msub$subclass)
# Summary SMD for age
weighted.mean(smds, ns)
#> [1] -0.2354095
bal.tab(msub)
#> Balance measures across subclasses
#> Type Diff.Adj
#> distance Distance 0.1081
#> age Contin. -0.2354
#> educ Contin. 0.0075
#> race_black Binary 0.0535
#> race_hispan Binary -0.0420
#> race_white Binary -0.0115
#> married Binary -0.1160
#> re74 Contin. -0.3200
#>
#> Sample sizes by subclass
#> 1 2 3 4 5 6 All
#> Control 102 100 88 72 39 28 429
#> Treated 4 4 9 30 62 76 185
#> Total 106 104 97 102 101 104 614
This works for mean differences but not other statistics. So the way
cobalt
actually does this is compute stratification
weights, and then compute the balance statistics using the
stratification weights in the full sample. Stratification weights are
first computed by computing the proportion of treated units in each
sample, and then using the formulas to compute propensity score weights
from propensity scores. Here’s how I do that manually for
age
:
# Compute proportion of treated units in each subclass
prop1 <- sapply(1:6, function(s) mean(lalonde$treat[msub$subclass == s]))
# Assign to each unit
ps <- prop1[msub$subclass]
# Compute ATE weights
w <- ifelse(lalonde$treat == 1, 1 / ps, 1 / (1 - ps))
# Compute weighted KS statistic
col_w_ks(lalonde$age, treat = lalonde$treat,
weights = w)
#> [1] 0.1658923
bal.tab(msub, stats = "ks")
#> Balance measures across subclasses
#> Type KS.Adj
#> distance Distance 0.2187
#> age Contin. 0.1659
#> educ Contin. 0.0627
#> race_black Binary 0.0535
#> race_hispan Binary 0.0420
#> race_white Binary 0.0115
#> married Binary 0.1160
#> re74 Contin. 0.3038
#>
#> Sample sizes by subclass
#> 1 2 3 4 5 6 All
#> Control 102 100 88 72 39 28 429
#> Treated 4 4 9 30 62 76 185
#> Total 106 104 97 102 101 104 614
cobalt
as I do when using tableone
?tableone
is another package that provides tools for
balance assessment. One strength that the package has is its beautiful,
publication-ready tables that include summary statistics for the
covariates, clean variable names, and clean headings. But it does not
incorporate best practices in balance assessment in favor of
transparency. This differs from the ethos of cobalt
, which
is to provide highly customizable balance statistics that reflect best
practices and use well-reasoned decisions. This is not an insult to
tableone
but is meant to reflect the different purposes
cobalt
and tableone
have. They should not be
used interchangeably or expect to yield identical results because they
use different formulas for computing certain statistics, most notably
the SMD.
Below are some of the reasons why SMDs might differ between
tableone
and cobalt
:
tableone
always uses the pooled standard deviation
(i.e., the standardizaton factor setting
s.d.denom = "pooled"
) as the standardization factor, while
cobalt
determines the standardization factor based on the
estimand (though by default or when the ATE is the estimand, the two
should be aligned).tableone
uses the weighted standardization factor in
the SMD, whereas cobalt
always uses the standardization
factor computed in the unadjusted sample. For matching, this means
tableone
computes the standardization factor in the matched
sample, while cobalt
uses the original sample.tableone
uses survey::svyvar()
to compute
weighted variances, whereas cobalt
uses the formula
described previously (and implemented in col_w_sd()
). These
values will differ by small amounts when the weights are not
constant.tableone
uses a single
statistic described by Yang and Dalton (2012) to
summarize balance, whereas cobalt
provides a balance
statistic for each level of the covariate. There is no reason to prefer
the statistic used by tableone
; it does not have any
relationship to the bias of the estimate and can mask large differences
in some categories when there are many categories. See here for a
more detailed answer.In practice, these differences will be small. Obviously, I recommend
using cobalt
instead for balance assessment, and I
recommend reporting the balance statistics cobalt
produces.
That said, if you understand what tableone
is doing and are
okay with the choices it makes, there is no denying that it can produce
beautiful tables.
For multi-category treatments, all standardization
factors are computed using the full data, not just the groups being
compared. For example, the pooled standard deviation involves computing
the mean of all the group-specific variances, not just the two being
compared. Similarly, in the "hedges"
formula, n − 2 is replaced with n − k, where k is the number of treatment
groups.↩︎