tidytlg
provides a framework of creating TLG outputs for
clinical study report. The TLG programming workflow includes the
following steps:
Prep environment: set up the R environment for the I/O paths.
Process data: filter analysis data, perform data manipulation (e.g. convert character variable to factor), and define column variable.
Generate results: create analysis rows of summary statistics (for tables) or plots (for graphs).
Output results: output analysis results in designated format such as rtf or html.
We will illustrate the above steps by creating a demographic table first, and then follow by examples of creating listing and graph.
To set up the R environment, you can set the path objects of the input folder and output folder consistently for all TLG programs. The analysis datasets and other required inputs such as the titles file and column metadata file are placed in the input folder, while the output folder will be used to store the output files. The envsetup package can be used to set up the R environment for TLG programming.
The information for titles and footnotes for each TLG can be stored in an excel file called titles.xls (see below snapshot), which will be used later to create the outputs.
Column metadata provides the column structure of the table layout and includes the following variables:
tbltype: identifier used to group a table column layout
coldef: distinct variable values used, typically numeric and typically a treatment variable, think TRT01PN
decode: decode of coldef that will display as a column header in the table
span1: spanning header to display across multiple columns (the lowest level)
span2: spanning header to display across multiple columns, second level
span3: spanning header to display across multiple columns, third level
Please see below for a snapshot of column_metadata.xlsx.
Different types of column layouts identified by different
tbltype
can be stored in an excel file called
column_metadata.xlsx. Within each tbltype
, the
coldef
variable defines the order of the column based on
the column variable used for creating the output (typically the numeric
treatment variable, TRT01PN, is used as the column variable). For
example, there are 3 columns for tbltype
= “type1” in the
above snapshot and the column layout is defined as follows: the first
column of summary statistics represents the treatment group of
TRT01PN = 0
with the column header of Placebo defined by
decode
, the second and third columns represent the Low Dose
and High Dose groups respectively with the spanning header of Xanomeline
defined by the span1
variable.
Users can also include the column that is derived from combination of
individual columns. For example, the tbltype
of type3
include the 4th column of combined Low Dose and High Dose as well as the
5th column of total group. Please see below for the snapshot of column
headers defined by type3.
We will use the adsl data from the PHUSE Test Data Factory to illustrate the creation of a demographic table.
# Prep Environment -------------------------------------------------------------------------------------
library(dplyr)
library(haven)
library(tidytlg)
# read adsl from PhUSE test data factory
testdata <- "https://github.com/phuse-org/TestDataFactory/raw/main/Updated/TDF_ADaM/"
adsl <- read_xpt(url(paste0(testdata,"adsl.xpt")))
Before generating analysis summary, the analysis data need to be processed first as shown in the code below.
# Process Data -----------------------------------------------------------------------------------------
adsl <- adsl %>%
filter(ITTFL == "Y") %>%
mutate(SEX = factor(SEX, levels = c("M", "F", "U"), labels = c("Male", "Female", "Unknown"))) %>%
tlgsetup(var = "TRT01PN",
column_metadata_file = system.file("extdata/column_metadata.xlsx", package = "tidytlg"),
tbltype = "type3")
The above code perform the tasks below:
filtering analysis population
convert the SEX
variable from character type to
factor type. So all the factor levels of SEX
will be
displayed in the analysis summary even there are no records for the
factor level of “Unknown”.
create the column variable, colnbr
, through the
tlgsetup
function call: tlgsetup
is using the
numeric treatment variable (e.g. TRT01PN
) to match with
coldef
in column metadata defined by
column_metadata_file
and tbltype
to create the
column variable, colnbr
, in adsl
for
reflecting the column layout. Please see the
vignette("tlgsetup")
for more details. The column variable,
colnbr
, will be used in the subsequent analysis function
calls for creating analysis results.
If you need multiple analysis datasets for creating TLG,
tlgsetup
will need to be applied to each dataset.
Therefore, you will have a consistent column variable of
colnbr
for creating analysis summary.
tidytlg
provides 3 functions, univar
,
freq
, and nested_freq
, to generate analysis
summary of descriptive statistics (univariate statistics and count
(percentages)). For more details, please see the frequency analysis
vignette("freq")
and the univariate statistical analysis
vignette("univar")
.
# Generate Results -------------------------------------------------------------------------------------
## Analysis set row
t1 <- adsl %>%
freq(colvar = "colnbr",
rowvar = "ITTFL",
statlist = statlist("n"),
subset = ITTFL == "Y",
rowtext = "Analysis set: ITT")
## Univariate summary for AGE
t2 <- adsl %>%
univar(colvar = "colnbr",
rowvar = "AGE",
statlist = statlist(c("N", "MEANSD", "MEDIAN", "RANGE", "IQRANGE")),
decimal = 0,
row_header = "Age, years")
## Count (percentages) for SEX
t3 <- adsl %>%
freq(colvar = "colnbr",
rowvar = "SEX",
statlist = statlist(c("N","n (x.x%)")),
row_header = "Gender")
The above function calls generate the requested analysis rows for the
table output sequentially and store the results in individual objects
(i.e. t1
, t2
, t3
). The next step
is to combine analysis results into a single tbl
dataframe
through the bind_table
function call.
# Format Results ---------------------------------------------------------------------------------------
tbl <- bind_table(t1, t2, t3,
column_metadata_file = system.file("extdata/column_metadata.xlsx", package = "tidytlg"),
tbltype = "type3")
The above bind_table
function call performs the
following tasks:
bind the analysis rows from t1
, t2
,
t3
into tbl
add formatting variables (indentme
,
newrows
, newpage
), which will be used in the
gentlg
function call below for creating the
output.
attach the column metadata specified by
column_metadata_file
and tbltype
as an
attribute of the tbl
. So the column header and the spanning
headers (i.e. decode, span1, span2, span3) defined in the column
metadata can be used automatically in the gentlg
function
call.
The tbl
data frame is the main input to the gentlg
function for creating the RTF/HTML outputs.
The basic structure of tbl includes label, col1, col2, …, coln, where
label: row text displayed on the 1st column of the table
col1: statistic results displayed on the 2nd column of the table
col2: statistic results displayed on the 3rd column of the table.
All other columns contain formatting instructions to create the
RTF/HTML outputs. For tweaking the formatting variables to customize the
table layout, please see the vignette("tbl_manipulation")
for more details.
label | col1 | col2 | col3 | col4 | col5 | row_type | anbr | indentme | roworder | newrows | newpage |
---|---|---|---|---|---|---|---|---|---|---|---|
Analysis set: ITT | 86 | 84 | 84 | 168 | 254 | HEADER | 1 | 0 | 1 | 0 | 0 |
Age, years | HEADER | 2 | 0 | 1 | 1 | 0 | |||||
N | 86 | 84 | 84 | 168 | 254 | N | 2 | 1 | 2 | 0 | 0 |
Mean (SD) | 75.2 (8.59) | 75.7 (8.29) | 74.4 (7.89) | 75.0 (8.09) | 75.1 (8.25) | VALUE | 2 | 2 | 3 | 0 | 0 |
Median | 76.0 | 77.5 | 76.0 | 77.0 | 77.0 | VALUE | 2 | 2 | 4 | 0 | 0 |
Range | (52; 89) | (51; 88) | (56; 88) | (51; 88) | (51; 89) | VALUE | 2 | 2 | 5 | 0 | 0 |
IQ range | (69.0; 82.0) | (71.0; 82.0) | (70.5; 80.0) | (71.0; 81.0) | (70.0; 81.0) | VALUE | 2 | 2 | 6 | 0 | 0 |
Gender | HEADER | 3 | 0 | 1 | 1 | 0 | |||||
N | 86 | 84 | 84 | 168 | 254 | N | 3 | 1 | 2 | 0 | 0 |
Male | 33 (38.4%) | 34 (40.5%) | 44 (52.4%) | 78 (46.4%) | 111 (43.7%) | VALUE | 3 | 2 | 3 | 0 | 0 |
Female | 53 (61.6%) | 50 (59.5%) | 40 (47.6%) | 90 (53.6%) | 143 (56.3%) | VALUE | 3 | 2 | 4 | 0 | 0 |
Unknown | 0 | 0 | 0 | 0 | 0 | VALUE | 3 | 2 | 5 | 0 | 0 |
The gentlg
function call below will create the rtf
output using the tblid
as the file name in the folder
defined by the opath
argument. Please ensure that the
titles.xls
file contains the records of titles and
footnotes for the specified tblid
.
tblid <- "Table01"
gentlg(huxme = tbl,
opath = file.path(working_dir),
file = tblid,
orientation = "landscape",
title_file = system.file("extdata/titles.xls", package = "tidytlg"))[[1]]
#> NULL
To create the html output, users need to specify the
format
argument as “HTML” and print.hux
argument as FALSE in the gentlg
call.
gentlg(huxme = tbl,
format = "HTML",
print.hux = FALSE,
file = tblid,
orientation = "landscape",
title_file = system.file("extdata/titles.xls", package = "tidytlg"))[[1]]
Table01: Demographic and Baseline Characteristics; Intent-to-treat Analysis Set | |||||
Xanomeline | |||||
Placebo | Low Dose | High Dose | Combined | Total | |
---|---|---|---|---|---|
Analysis set: ITT | 86 | 84 | 84 | 168 | 254 |
Age, years | |||||
N | 86 | 84 | 84 | 168 | 254 |
Mean (SD) | 75.2 (8.59) | 75.7 (8.29) | 74.4 (7.89) | 75.0 (8.09) | 75.1 (8.25) |
Median | 76.0 | 77.5 | 76.0 | 77.0 | 77.0 |
Range | (52; 89) | (51; 88) | (56; 88) | (51; 88) | (51; 89) |
IQ range | (69.0; 82.0) | (71.0; 82.0) | (70.5; 80.0) | (71.0; 81.0) | (70.0; 81.0) |
Gender | |||||
N | 86 | 84 | 84 | 168 | 254 |
Male | 33 (38.4%) | 34 (40.5%) | 44 (52.4%) | 78 (46.4%) | 111 (43.7%) |
Female | 53 (61.6%) | 50 (59.5%) | 40 (47.6%) | 90 (53.6%) | 143 (56.3%) |
Unknown | 0 | 0 | 0 | 0 | 0 |
Key: IQ = interquartile | |||||
Note: N reflects non-missing values | |||||
[table01.html][] 30OCT2024, 05:16 |
Users can also include superscripts, subscripts, or line breaks via
unicode. Please see the vignette("symbols")
for more
details. Besides using univar
, freq
, and
nested_freq
functions to create the tbl
dataframe, users can use other R packages to create analysis results and
perform data wrangling to fit the tbl
structure, which can
be passed into the gentlg
function call for generating the
desired outputs.
The above workflow can also be used to create listings. Users need to
prepare the data and assign it to tbl
. In the
gentlg
function, users need to pay attention to:
specify the tlf
argument to Listing
(i.e. tlf = "Listing"
)
specify the idvars
argument for identifying
variables (such as treatment variable and USUBJID) where repeated values
will be removed
specify the colheader
(column header) argument; if
not specified, the column labels will be used as the column headers. For
the below example, if colheader
argument is not specified,
some column headers will use variable names since these columns are
newly created without labels.
user has the option to control the column width by passing a
vector of column width to the wcol
argument. Please ensure
that the length of the column width vector is the same as the number of
columns in your data. For the example below, there are 8 columns in the
data and users can specify customized column width such as
c(0.15, 0.10, 0.05, 0.15, 0.20, 0.15, 0.05, 0.05)
for the
wcol
argument to create the rtf output. However, for the
html output shown here, the wcol
argument can only take a
single number as the column width and apply to every column.
# Prep Environment ---------------------------------------------------------------------------------------
library(dplyr)
library(haven)
library(tidytlg)
adsl <- cdisc_adsl
adae <- cdisc_adae
# Process Data --------------------------------------------------------------------------------------------
adsl <- adsl %>%
filter(SAFFL == "Y") %>%
select(USUBJID, SAFFL, TRT01AN, TRT01A)
adae <- adae %>%
filter(SAFFL == "Y" & TRTEMFL == "Y") %>%
mutate(BSPT = paste(AEBODSYS, "[", AEDECOD, "]"),
SAEFL = if_else(AESER == "Y", "Yes", "No"),
DTHFL = if_else(AEOUT == "FATAL", "Yes", "No")) %>%
select(USUBJID, ASTDY, TRTA, BSPT, AETERM, SAEFL, DTHFL)
tbl <- inner_join(adsl, adae, by = "USUBJID") %>%
arrange(TRT01AN, USUBJID, ASTDY) %>%
select(TRT01A, USUBJID, ASTDY, TRTA, BSPT, AETERM, SAEFL, DTHFL) %>%
filter(USUBJID %in% c("01-701-1015", "01-701-1023"))
# Output Results ------------------------------------------------------------------------------------------
gentlg(huxme = tbl,
tlf = "l",
format = "HTML",
print.hux = FALSE,
orientation = "landscape",
file = "Listing01",
title = "Listing of Adverse Events",
idvars = c("TRT01A", "USUBJID"),
wcol = 0.15,
colheader = c("Treatment Group",
"Subject ID",
"Study Day of AE",
"Treatment Period",
"Body System [Preferred Term]",
"Verbatim Term",
"Serious",
"Fatal"))[[1]]
Listing01: Listing of Adverse Events | |||||||
Treatment Group | Subject ID | Study Day of AE | Treatment Period | Body System [Preferred Term] | Verbatim Term | Serious | Fatal |
---|---|---|---|---|---|---|---|
Placebo | 01-701-1015 | 2 | Placebo | GENERAL DISORDERS AND ADMINISTRATION SITE CONDITIONS [ APPLICATION SITE ERYTHEMA ] | APPLICATION SITE ERYTHEMA | No | No |
2 | Placebo | GENERAL DISORDERS AND ADMINISTRATION SITE CONDITIONS [ APPLICATION SITE PRURITUS ] | APPLICATION SITE PRURITUS | No | No | ||
8 | Placebo | GASTROINTESTINAL DISORDERS [ DIARRHOEA ] | DIARRHOEA | No | No | ||
01-701-1023 | 3 | Placebo | SKIN AND SUBCUTANEOUS TISSUE DISORDERS [ ERYTHEMA ] | ERYTHEMA | No | No | |
3 | Placebo | SKIN AND SUBCUTANEOUS TISSUE DISORDERS [ ERYTHEMA ] | ERYTHEMA | No | No | ||
3 | Placebo | SKIN AND SUBCUTANEOUS TISSUE DISORDERS [ ERYTHEMA ] | ERYTHEMA | No | No | ||
22 | Placebo | CARDIAC DISORDERS [ ATRIOVENTRICULAR BLOCK SECOND DEGREE ] | ATRIOVENTRICULAR BLOCK SECOND DEGREE | No | No | ||
[listing01.html][] 30OCT2024, 05:16 |
To create the graph output, tidytlg
provides a framework
of integrating the png file with titles and footnotes for producing the
rtf or html output.
In the gentlg
function, users need to:
specify the tlf
argument to g
for
graph
specify the plotnames
argument with the full path of
the png file
define the plotwidth
and plotheight
:
it’s advised here that users keep the aspect ratio of plot width and
height approximately the same as the png image.
The code below will create the rtf output of the plot.
# Prep Environment ---------------------------------------------------------------------------------------
library(dplyr)
library(haven)
library(ggplot2)
#>
#> Attaching package: 'ggplot2'
#> The following object is masked from 'package:huxtable':
#>
#> theme_grey
library(tidytlg)
# read adsl from PhUSE test data factory
testdata <- "https://github.com/phuse-org/TestDataFactory/raw/main/Updated/TDF_ADaM/"
adsl <- read_xpt(url(paste0(testdata,"adsl.xpt")))
tblid <- "Graph01"
# Process Data --------------------------------------------------------------------------------------------
adsl <- adsl %>%
filter(ITTFL == "Y") %>%
select(USUBJID, ITTFL, TRT01PN, TRT01P, AGE, SEX, HEIGHTBL, WEIGHTBL) %>%
mutate(SEX = factor(SEX, levels = c("M", "F"), labels = c("Male", "Female")))
# Generate Results ----------------------------------------------------------------------------------------
plot <- ggplot(data = adsl, aes(x = HEIGHTBL, y = WEIGHTBL)) +
geom_point() +
labs(x = "Baseline Height (cm)",
y = "Baseline Weight (kg)") +
facet_wrap(~SEX, nrow=1)
# create png file
png(file.path(working_dir, paste0(tblid,".png")), width=2800, height=1300, res=300, type = "cairo")
plot
#> Warning: Removed 1 row containing missing values or values outside the scale range
#> (`geom_point()`).
dev.off()
#> png
#> 2
# Output Results ------------------------------------------------------------------------------------------
gentlg(tlf = "g",
plotnames = file.path(system.file("extdata", package = "tidytlg"), paste0(tblid,".png")),
plotwidth = 10,
plotheight = 5,
orientation = "landscape",
opath = file.path(working_dir),,
file = tblid,
title_file = system.file("extdata/titles.xls", package = "tidytlg"))
Besides building the table section-by-section as shown above, we can
use the table metadata approach as an efficient alternative for
generating outputs. Table metadata is a data frame describing the data,
functions and arguments needed to produce your table results. The table
metadata shown below can be used to create the same table output as
above. Each row in the table metadata describes how a tbl
chunk will be created by the function defined in the func
column. The rest of the columns defines the arguments
(i.e. df
, colvar
, rowvar
,
statlist
, rowtext
, row_header
)
that will be passed into the function.
Once table metadata is defined, users just need to call the
generate_results
function with the column metadata define
in the column_metadata_file
and tbltype
arguments to create the tbl
dataframe. In the processing
data step, users don’t need to call tlgsetp
, since
tlgsetup
is embedded within the
generate_results
function. That’s why we need to specify
the column metadata in the generate_results
call.
library(dplyr)
library(haven)
library(tidytlg)
# read adsl from PhUSE test data factory
testdata <- "https://github.com/phuse-org/TestDataFactory/raw/main/Updated/TDF_ADaM/"
adsl <- read_xpt(url(paste0(testdata,"adsl.xpt")))
# Process data
adsl <- adsl %>%
filter(ITTFL == "Y") %>%
mutate(SEX = factor(SEX, levels = c("M", "F", "U"), labels = c("Male", "Female", "Unknown")))
# define table metadata
table_metadata <- tibble::tribble(
~func, ~df, ~rowvar, ~decimal, ~rowtext, ~row_header, ~statlist, ~subset,
"freq", "adsl", "ITTFL", NA, "Analysis set: ITT", NA, statlist("n"), "ITTFL == 'Y'",
"univar", "adsl", "AGE", 0, NA, "Age (Years)", NA, NA,
"freq", "adsl", "SEX", NA, NA, "Gender", statlist(c("N", "n (x.x%)")), NA
) %>%
mutate(colvar = "TRT01PN")
# Generate results
tbl <- generate_results(table_metadata,
column_metadata_file = system.file("extdata/column_metadata.xlsx", package = "tidytlg"),
tbltype = "type3")
# Output results
tblid <- "Table01"
gentlg(huxme = tbl,
format = "HTML",
print.hux = FALSE,
file = tblid,
orientation = "landscape",
title_file = system.file("extdata/titles.xls", package = "tidytlg"))[[1]]
Table01: Demographic and Baseline Characteristics; Intent-to-treat Analysis Set | |||||
Xanomeline | |||||
Placebo | Low Dose | High Dose | Combined | Total | |
---|---|---|---|---|---|
Analysis set: ITT | 86 | 84 | 84 | 168 | 254 |
Age (Years) | |||||
N | 86 | 84 | 84 | 168 | 254 |
Mean (SD) | 75.2 (8.59) | 75.7 (8.29) | 74.4 (7.89) | 75.0 (8.09) | 75.1 (8.25) |
Median | 76.0 | 77.5 | 76.0 | 77.0 | 77.0 |
Range | (52; 89) | (51; 88) | (56; 88) | (51; 88) | (51; 89) |
IQ range | (69.0; 82.0) | (71.0; 82.0) | (70.5; 80.0) | (71.0; 81.0) | (70.0; 81.0) |
Gender | |||||
N | 86 | 84 | 84 | 168 | 254 |
Male | 33 (38.4%) | 34 (40.5%) | 44 (52.4%) | 78 (46.4%) | 111 (43.7%) |
Female | 53 (61.6%) | 50 (59.5%) | 40 (47.6%) | 90 (53.6%) | 143 (56.3%) |
Unknown | 0 | 0 | 0 | 0 | 0 |
Key: IQ = interquartile | |||||
Note: N reflects non-missing values | |||||
[table01.html][] 30OCT2024, 05:16 |
There are two types of by-processing that tidytlg
functions can provide:
rowbyvar
: split the summary statistics of
rowvar
by other variable(s) specified in
rowbyvar
. Please see the by processing section of frequency
analysis vignette("freq")
for further details. The
rowbyvar
argument can also be used in the
univar
function. A typical use case is to summarize the lab
values by parameter and analysis visit, where we can call the
univar
function with rowvar = AVAL
and
rowbyvar = c("PARAM","AVISIT")
. It is advised in this use
case to turn on the .ord
argument
(i.e. .ord = TRUE
) in the univar
function
call. So the numeric sorting columns associated with the by variables
(PARAM_ord
and AVISIT_ord
) can be created and
used for sorting the interleaved summary results of AVAL
and CHG
.
tablebyvar
: the argument of tablebyvar
is designed to facilitate the sub-group analysis, which repeats a table
summary by the sub-group variable. A typical use case is the summary of
demographics table by country. For creating the sub-group analysis
version of the same table, we just need to add the argument of
tablebyvar
with the sub-group variable in each function
call.
The code below provides an example of summarizing age and race by
gender using tablebyvar
.
library(dplyr)
library(haven)
library(tidytlg)
# read adsl from PhUSE test data factory
testdata <- "https://github.com/phuse-org/TestDataFactory/raw/main/Updated/TDF_ADaM/"
adsl <- read_xpt(url(paste0(testdata,"adsl.xpt")))
# Process data
adsl <- adsl %>%
filter(ITTFL == "Y") %>%
mutate(SEX = factor(SEX, levels = c("M", "F"), labels = c("Male", "Female")))
# define table metadata
table_metadata <- tibble::tribble(
~func, ~df, ~rowvar, ~decimal, ~rowtext, ~row_header, ~statlist, ~subset, ~tablebyvar,
"univar", "adsl", "AGE", 0, NA, "Age (Years)", NA, NA, "SEX",
"freq", "adsl", "RACE", NA, NA, "Race", statlist(c("N", "n (x.x%)")), NA, "SEX"
) %>%
mutate(colvar = "TRT01PN")
# Generate results
tbl <- generate_results(table_metadata,
column_metadata_file = system.file("extdata/column_metadata.xlsx", package = "tidytlg"),
tbltype = "type3")
# Output results
tblid <- "Table01"
gentlg(huxme = tbl,
format = "HTML",
print.hux = FALSE,
file = tblid,
orientation = "landscape",
title_file = system.file("extdata/titles.xls", package = "tidytlg"))[[1]]
Table01: Demographic and Baseline Characteristics; Intent-to-treat Analysis Set | |||||
Xanomeline | |||||
Placebo | Low Dose | High Dose | Combined | Total | |
---|---|---|---|---|---|
Male | |||||
Age (Years) | |||||
N | 33 | 34 | 44 | 78 | 111 |
Mean (SD) | 73.4 (8.15) | 75.6 (8.69) | 74.1 (8.16) | 74.8 (8.37) | 74.4 (8.29) |
Median | 74.0 | 77.5 | 77.0 | 77.0 | 77.0 |
Range | (52; 85) | (51; 88) | (56; 86) | (51; 88) | (51; 88) |
IQ range | (69.0; 80.0) | (68.0; 82.0) | (69.0; 80.5) | (69.0; 81.0) | (69.0; 81.0) |
Race | |||||
N | 33 | 34 | 44 | 78 | 111 |
AMERICAN INDIAN OR ALASKA NATIVE | 0 | 0 | 1 (2.3%) | 1 (1.3%) | 1 (0.9%) |
BLACK OR AFRICAN AMERICAN | 3 (9.1%) | 0 | 3 (6.8%) | 3 (3.8%) | 6 (5.4%) |
WHITE | 30 (90.9%) | 34 (100.0%) | 40 (90.9%) | 74 (94.9%) | 104 (93.7%) |
Female | |||||
Age (Years) | |||||
N | 53 | 50 | 40 | 90 | 143 |
Mean (SD) | 76.4 (8.73) | 75.7 (8.09) | 74.7 (7.67) | 75.2 (7.88) | 75.7 (8.19) |
Median | 78.0 | 77.5 | 76.0 | 76.0 | 77.0 |
Range | (59; 89) | (54; 87) | (56; 88) | (54; 88) | (54; 89) |
IQ range | (70.0; 84.0) | (72.0; 81.0) | (72.0; 79.0) | (72.0; 81.0) | (72.0; 81.0) |
Race | |||||
N | 53 | 50 | 40 | 90 | 143 |
AMERICAN INDIAN OR ALASKA NATIVE | 0 | 0 | 0 | 0 | 0 |
BLACK OR AFRICAN AMERICAN | 5 (9.4%) | 6 (12.0%) | 6 (15.0%) | 12 (13.3%) | 17 (11.9%) |
WHITE | 48 (90.6%) | 44 (88.0%) | 34 (85.0%) | 78 (86.7%) | 126 (88.1%) |
Key: IQ = interquartile | |||||
Note: N reflects non-missing values | |||||
[table01.html][] 30OCT2024, 05:16 |
In summary, rowbyvar
is used to create the by-variable
summary for one rowvar
in a single function call. To
perform sub-group analysis, users need to specify
tablebyvar
in every function calls except the analysis
population row.