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library(moder)
What makes moder special is the way it handles missing values. It has two main guiding principles:
NA
if and only if the data
cannot answer the user’s question.Both points directly follow from R’s general approach towards missing values. This vignette explains them in some detail. Finally, it spells out the underlying theory. I recommend reading “Get started” first if you haven’t already.
NA
only if question can’t be answeredNA
is not some other value that shows up in the data. It
is a placeholder for any and all values that we don’t know, so we should
treat it accordingly. This is why mean()
and
median()
sometimes return NA
:
<- c(7, 7, 7, 8, 8, 9, 9, NA)
x1 mean(x1)
#> [1] NA
median(x1)
#> [1] NA
We don’t know the true value behind NA
, so we don’t know
how it would influence the mean or the median. This is always true for
the mean (but not for the median).1 What about the mode? Missing values will
sometimes, but not always, render it unknown. Therefore, mode
implementations require special care and nuance.
In x1
, we know that 7
is a mode. It appears
three times, and even if the NA
was actually an
8
or a 9
, that value would only appear three
times, as well. This means we know one mode, but not necessarily the
whole set of modes. mode_first()
is happy to return
7
, but mode_all()
insists on the complete set
of modes. It can’t be determined, so the function returns
NA
:
x1#> [1] 7 7 7 8 8 9 9 NA
mode_first(x1)
#> [1] 7
mode_all(x1)
#> [1] NA
Some distributions have a clear set of modes even though some of its
values are missing. Here, 1
is more frequent than
0
even if each NA
masks another
0
:
<- c(1, 1, 1, 1, 1, 0, 0, NA, NA)
x2 mode_first(x2)
#> [1] 1
mode_all(x2)
#> [1] 1
Where is mode_single()
in all of this? It calls
mode_all()
internally, so it handles missing values just
like this function does. Differences only occur if
mode_all()
returns multiple modes.
All of these functions attempt to find modal values. However, moder
also has some functions that are not concerned about any particular
modes but only assess metadata, such as the modal frequency. This is why
they can sometimes obtain useful information where
mode_first()
and friends would only return NA
.
Even if the number or frequency of modes can’t be determined, at least a
range for them can be given. See vignette("metadata")
to
learn more.
In particular, all the metadata functions have a
max_unique
argument. It allows you to encode some knowledge
you might have about the missing values in your data. See
vignette("metadata")
, section Maximal number of unique
values.
You might want to find all values that are known to be modes, even if
missing values make it unclear whether certain other values are. Use
mode_possible_min()
for this. You can think of the function
as a less strict version of mode_all()
: It also takes all
modes it can find, but unlike mode_all()
, it doesn’t insist
on the full set of modes.
Either 8
or 9
may be a mode, depending on
NA
, but 7
is a mode in any case:
x1#> [1] 7 7 7 8 8 9 9 NA
mode_possible_min(x1)
#> [1] 7
Here, "a"
is definitely a mode, "b"
is only
a mode if the missing value is also "b"
, but
"c"
can’t be a mode:
mode_possible_min(c("a", "a", "a", "b", "b", "c", NA))
#> [1] "a"
Other distributions may not have a clear minimum because too many of
its values are missing. If both NA
s below are
FALSE
, then FALSE
is the mode. Otherwise,
TRUE
is:
mode_possible_min(c(TRUE, TRUE, FALSE, NA, NA))
#> [1] NA
The mirror image of mode_possible_min()
is
mode_possible_max()
. It returns the greatest possible set
of modes, given the number of missing values. This is all about the
theoretical maximum, so the function can return values that are not
guaranteed to be modes!
As above, "a"
is a known mode, "b"
may be a
mode, but "c"
can’t be one:
mode_possible_max(c("a", "a", "a", "b", "b", "c", NA))
#> [1] "a" "b"
There is no clear maximum in x1
because either
8
or 9
can be a mode, but not both together.
With one more 7
, though, 7
is more frequent
anyways:
x1#> [1] 7 7 7 8 8 9 9 NA
mode_possible_max(x1)
#> [1] NA
mode_possible_max(c(x1, 7))
#> [1] 7
NA
value only if chosen by
userNA
sEach moder function that attempts to determine (actual) modes has an
na.rm
argument. This works exactly like in
mean()
and median()
: It’s FALSE
by default, but if the user sets it to TRUE
, missing values
are removed from x
before the statistic is computed.
x1#> [1] 7 7 7 8 8 9 9 NA
mean(x1, na.rm = TRUE)
#> [1] 7.857143
median(x1, na.rm = TRUE)
#> [1] 8
mode_all(x1, na.rm = TRUE)
#> [1] 7
You should think really carefully before removing NA
s.
Are you sure the missing values are unnecessary to answer your specific
question?
This approach makes sure to inform the user if the data can’t answer their questions. They might still choose to ignore missings, but this will always require an explicit statement. In this way, users will know what they are doing, and can make their own decisions about data analysis.
mode_first()
has a Boolean accept
argument
that is FALSE
by default. If set to TRUE
, the
function will pick the first value known to be a mode. This means it
won’t strictly look for the first-appearing value that is a mode, but
accept the first value that is a mode without counting NA
s
in its favor:
<- c(6, 4, 4, 4, NA, NA, 1)
x4 mode_first(x4)
#> [1] NA
mode_first(x4, accept = TRUE)
#> [1] 4
The NA
s might both be 6
, and a known
6
appears at the very start, so this might be the first
mode. It’s unclear, so we get NA
by default. However,
4
is the first value that we know is a mode.
Setting accept
to TRUE
makes the function
pragmatically accept 4
— we want to find a mode, after all,
and we know one.
In mode_single()
as well, accept
is
FALSE
by default. The purpose is to check whether there is
exactly one mode by using the complete set of modes, not the minimum set
that just so happens to be known. Set accept
to
TRUE
to avoid returning NA
when one mode is
known, but not all modes are:
<- c(4, 4, 4, 7, 7, NA)
x5 mode_single(x5)
#> [1] NA
mode_single(x5, accept = TRUE)
#> [1] 4
NA
s seriously enoughSome earlier mode functions for R treat NA
like a known
and constant value. This is suboptimal because NA
means
that a value is missing. Such an approach effectively assumes that all
NA
s represent the same unknown value, and that it’s
different from all known values (although I’m sure this was not the
intention).
Rather than forming a distinct and cohesive group, however, the
NA
s may represent one or more known or unknown values, so
this procedure can distort the data. Consider that NA == NA
returns NA
: If any two values are unknown, it’s also
unknown whether they are equal (Wickham 2019, ch. 3.2.3).
What’s more, categorizing missing values as a separate group is
actually an imputation strategy — and perhaps not a very wise one. I
think imputation by default is not the job of operations that are
supposed to simply determine a statistic. All moder functions treat
NA
s as genuinely missing values, just like
mean()
, median()
, and language primitives such
as ==
do. Sometimes, this means the functions can just
ignore them because a known value is more frequent than the
next-most-frequent value and all NA
s taken together. They
will only return NA
if the user’s question cannot possibly
be answered by the data.
All choices about imputation will then be left to the user. In this way, moder functions draw a clear line between estimation and imputation.
NA
s too seriouslyCertain other mode implementations return NA
whenever
the input vector contains any NA
s at all. This is not
necessary — in fact, it’s overly conservative. We have seen above that a
distribution may have a clear set of modes even if some of its values
are missing. This is a marked difference to mean()
, where
any missings really do make estimation impossible.
It all depends on the relation between counts: Is the most frequent
known value at least as frequent as the sum of the counts of the
second-most-frequent known value and all missing values? If so, this
value is known to be the mode. Note that mode_first()
,
mode_all()
and mode_single()
don’t allow for
ties among known values if any other values are missing (they return
NA
). That is because missings may secretly count for any
“tied” known value, which would break the tie.
In a vector like c(1, 1, NA)
, the mode is clearly
1
, no matter what the NA
stands for. It is
just as clear as in c(1, 1, 2)
. A mode function that
returns NA
instead of 1
would be incorrect for
c(1, 1, 2)
, so it would be just as incorrect for
c(1, 1, NA)
.
Again, think of the parallels to base R. NA ^ 2
returns
NA
, but NA ^ 0
returns 1
. In the
second case, we don’t need to know the true value behind NA
to determine the result. Such knowledge is built into R (Wickham 2019,
ch. 3.2.3),
and I think function design should emulate this pattern to keep the
semantics of NA
consistent across contexts.
NA
return typesIf a function that is supposed to return one or more modes returns
NA
instead, this NA
has the same type as the
input vector, x
. Functions that attempt to count modes or
to determine their frequency only ever return these integers or
NA_integer_
, i.e., a missing value of type integer.
However, the differences between NA
types are not very
important (and perhaps not widely known). They can usually be
disregarded.
Wickham, H. (2019). Advanced R (Second Edition), CRC Press/Taylor and Francis Group. https://adv-r.hadley.nz/index.html.
The median has some of the same complexities as the
mode. In a vector like c(1, 1, NA)
or even
c(1, 1, 1, 1, 2, 2, NA)
, the median is known to be
1
, regardless of the value behind NA
. This
raises some questions about the way stats::median.default()
handles missing values. See the naidem package for a
solution to this issue.↩︎
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.
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