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# ==================================================================== #
# TITLE #
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# AMR: An R Package for Working with Antimicrobial Resistance Data #
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# #
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# SOURCE #
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# https://github.com/msberends/AMR #
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# #
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# CITE AS #
# Berends MS, Luz CF, Friedrich AW, Sinha BNM, Albers CJ, Glasner C #
# (2022). AMR: An R Package for Working with Antimicrobial Resistance #
# Data. Journal of Statistical Software, 104(3), 1-31. #
# doi:10.18637/jss.v104.i03 #
# #
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# Developed at the University of Groningen and the University Medical #
# Center Groningen in The Netherlands, in collaboration with many #
# colleagues from around the world, see our website. #
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# #
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# This R package is free software; you can freely use and distribute #
# it for both personal and commercial purposes under the terms of the #
# GNU General Public License version 2.0 (GNU GPL-2), as published by #
# the Free Software Foundation. #
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# We created this package for both routine data analysis and academic #
# research and it was publicly released in the hope that it will be #
# useful, but it comes WITHOUT ANY WARRANTY OR LIABILITY. #
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# #
# Visit our website for the full manual and a complete tutorial about #
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# how to conduct AMR data analysis: https://msberends.github.io/AMR/ #
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# ==================================================================== #
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#' Age in Years of Individuals
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#'
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#' Calculates age in years based on a reference date, which is the system date at default.
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#' @param x date(s), [character] (vectors) will be coerced with [as.POSIXlt()]
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#' @param reference reference date(s) (default is today), [character] (vectors) will be coerced with [as.POSIXlt()]
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#' @param exact a [logical] to indicate whether age calculation should be exact, i.e. with decimals. It divides the number of days of [year-to-date](https://en.wikipedia.org/wiki/Year-to-date) (YTD) of `x` by the number of days in the year of `reference` (either 365 or 366).
#' @param na.rm a [logical] to indicate whether missing values should be removed
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#' @param ... arguments passed on to [as.POSIXlt()], such as `origin`
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#' @details Ages below 0 will be returned as `NA` with a warning. Ages above 120 will only give a warning.
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#'
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#' This function vectorises over both `x` and `reference`, meaning that either can have a length of 1 while the other argument has a larger length.
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#' @return An [integer] (no decimals) if `exact = FALSE`, a [double] (with decimals) otherwise
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#' @seealso To split ages into groups, use the [age_groups()] function.
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#' @export
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#' @examples
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#' # 10 random pre-Y2K birth dates
#' df <- data.frame(birth_date = as.Date("2000-01-01") - runif(10) * 25000)
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#'
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#' # add ages
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#' df$age <- age(df$birth_date)
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#'
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#' # add exact ages
#' df$age_exact <- age(df$birth_date, exact = TRUE)
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#'
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#' # add age at millenium switch
#' df$age_at_y2k <- age(df$birth_date, "2000-01-01")
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#'
#' df
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age <- function ( x , reference = Sys.Date ( ) , exact = FALSE , na.rm = FALSE , ... ) {
meet_criteria ( x , allow_class = c ( " character" , " Date" , " POSIXt" ) )
meet_criteria ( reference , allow_class = c ( " character" , " Date" , " POSIXt" ) )
meet_criteria ( exact , allow_class = " logical" , has_length = 1 )
meet_criteria ( na.rm , allow_class = " logical" , has_length = 1 )
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if ( length ( x ) != length ( reference ) ) {
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if ( length ( x ) == 1 ) {
x <- rep ( x , length ( reference ) )
} else if ( length ( reference ) == 1 ) {
reference <- rep ( reference , length ( x ) )
} else {
stop_ ( " `x` and `reference` must be of same length, or `reference` must be of length 1." )
}
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}
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x <- as.POSIXlt ( x , ... )
reference <- as.POSIXlt ( reference , ... )
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# from https://stackoverflow.com/a/25450756/4575331
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years_gap <- reference $ year - x $ year
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ages <- ifelse ( reference $ mon < x $ mon | ( reference $ mon == x $ mon & reference $ mday < x $ mday ) ,
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as.integer ( years_gap - 1 ) ,
as.integer ( years_gap )
)
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# add decimals
if ( exact == TRUE ) {
# get dates of `x` when `x` would have the year of `reference`
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x_in_reference_year <- as.POSIXlt (
paste0 (
format ( as.Date ( reference ) , " %Y" ) ,
format ( as.Date ( x ) , " -%m-%d" )
) ,
format = " %Y-%m-%d"
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)
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# get differences in days
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n_days_x_rest <- as.double ( difftime ( as.Date ( reference ) ,
as.Date ( x_in_reference_year ) ,
units = " days"
) )
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# get numbers of days the years of `reference` has for a reliable denominator
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n_days_reference_year <- as.POSIXlt ( paste0 ( format ( as.Date ( reference ) , " %Y" ) , " -12-31" ) ,
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format = " %Y-%m-%d"
) $ yday + 1
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# add decimal parts of year
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mod <- n_days_x_rest / n_days_reference_year
# negative mods are cases where `x_in_reference_year` > `reference` - so 'add' a year
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mod [ ! is.na ( mod ) & mod < 0 ] <- mod [ ! is.na ( mod ) & mod < 0 ] + 1
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# and finally add to ages
ages <- ages + mod
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}
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if ( any ( ages < 0 , na.rm = TRUE ) ) {
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ages [ ! is.na ( ages ) & ages < 0 ] <- NA
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warning_ ( " in `age()`: NAs introduced for ages below 0." )
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}
if ( any ( ages > 120 , na.rm = TRUE ) ) {
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warning_ ( " in `age()`: some ages are above 120." )
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}
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if ( isTRUE ( na.rm ) ) {
ages <- ages [ ! is.na ( ages ) ]
}
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if ( exact == TRUE ) {
as.double ( ages )
} else {
as.integer ( ages )
}
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}
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#' Split Ages into Age Groups
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#'
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#' Split ages into age groups defined by the `split` argument. This allows for easier demographic (antimicrobial resistance) analysis.
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#' @param x age, e.g. calculated with [age()]
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#' @param split_at values to split `x` at - the default is age groups 0-11, 12-24, 25-54, 55-74 and 75+. See *Details*.
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#' @param na.rm a [logical] to indicate whether missing values should be removed
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#' @details To split ages, the input for the `split_at` argument can be:
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#'
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#' * A [numeric] vector. A value of e.g. `c(10, 20)` will split `x` on 0-9, 10-19 and 20+. A value of only `50` will split `x` on 0-49 and 50+.
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#' The default is to split on young children (0-11), youth (12-24), young adults (25-54), middle-aged adults (55-74) and elderly (75+).
#' * A character:
#' - `"children"` or `"kids"`, equivalent of: `c(0, 1, 2, 4, 6, 13, 18)`. This will split on 0, 1, 2-3, 4-5, 6-12, 13-17 and 18+.
#' - `"elderly"` or `"seniors"`, equivalent of: `c(65, 75, 85)`. This will split on 0-64, 65-74, 75-84, 85+.
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#' - `"fives"`, equivalent of: `1:20 * 5`. This will split on 0-4, 5-9, ..., 95-99, 100+.
#' - `"tens"`, equivalent of: `1:10 * 10`. This will split on 0-9, 10-19, ..., 90-99, 100+.
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#' @return Ordered [factor]
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#' @seealso To determine ages, based on one or more reference dates, use the [age()] function.
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#' @export
#' @examples
#' ages <- c(3, 8, 16, 54, 31, 76, 101, 43, 21)
#'
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#' # split into 0-49 and 50+
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#' age_groups(ages, 50)
#'
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#' # split into 0-19, 20-49 and 50+
#' age_groups(ages, c(20, 50))
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#'
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#' # split into groups of ten years
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#' age_groups(ages, 1:10 * 10)
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#' age_groups(ages, split_at = "tens")
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#'
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#' # split into groups of five years
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#' age_groups(ages, 1:20 * 5)
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#' age_groups(ages, split_at = "fives")
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#'
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#' # split specifically for children
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#' age_groups(ages, c(1, 2, 4, 6, 13, 18))
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#' age_groups(ages, "children")
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#'
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#' \donttest{
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#' # resistance of ciprofloxacin per age group
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#' if (require("dplyr") && require("ggplot2")) {
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#' example_isolates %>%
#' filter_first_isolate() %>%
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#' filter(mo == as.mo("Escherichia coli")) %>%
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#' group_by(age_group = age_groups(age)) %>%
#' select(age_group, CIP) %>%
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#' ggplot_sir(
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#' x = "age_group",
#' minimum = 0,
#' x.title = "Age Group",
#' title = "Ciprofloxacin resistance per age group"
#' )
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#' }
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#' }
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age_groups <- function ( x , split_at = c ( 12 , 25 , 55 , 75 ) , na.rm = FALSE ) {
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meet_criteria ( x , allow_class = c ( " numeric" , " integer" ) , is_positive_or_zero = TRUE , is_finite = TRUE )
meet_criteria ( split_at , allow_class = c ( " numeric" , " integer" , " character" ) , is_positive_or_zero = TRUE , is_finite = TRUE )
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meet_criteria ( na.rm , allow_class = " logical" , has_length = 1 )
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if ( any ( x < 0 , na.rm = TRUE ) ) {
x [x < 0 ] <- NA
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warning_ ( " in `age_groups()`: NAs introduced for ages below 0." )
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}
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if ( is.character ( split_at ) ) {
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split_at <- split_at [1L ]
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if ( split_at %like% " ^(child|kid|junior)" ) {
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split_at <- c ( 0 , 1 , 2 , 4 , 6 , 13 , 18 )
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} else if ( split_at %like% " ^(elder|senior)" ) {
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split_at <- c ( 65 , 75 , 85 )
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} else if ( split_at %like% " ^five" ) {
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split_at <- 1 : 20 * 5
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} else if ( split_at %like% " ^ten" ) {
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split_at <- 1 : 10 * 10
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}
}
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split_at <- sort ( unique ( as.integer ( split_at ) ) )
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if ( ! split_at [1 ] == 0 ) {
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# add base number 0
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split_at <- c ( 0 , split_at )
}
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split_at <- split_at [ ! is.na ( split_at ) ]
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stop_if ( length ( split_at ) == 1 , " invalid value for `split_at`" ) # only 0 is available
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# turn input values to 'split_at' indices
y <- x
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lbls <- split_at
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for ( i in seq_len ( length ( split_at ) ) ) {
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y [x >= split_at [i ] ] <- i
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# create labels
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lbls [i - 1 ] <- paste0 ( unique ( c ( split_at [i - 1 ] , split_at [i ] - 1 ) ) , collapse = " -" )
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}
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# last category
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lbls [length ( lbls ) ] <- paste0 ( split_at [length ( split_at ) ] , " +" )
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agegroups <- factor ( lbls [y ] , levels = lbls , ordered = TRUE )
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if ( isTRUE ( na.rm ) ) {
agegroups <- agegroups [ ! is.na ( agegroups ) ]
}
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agegroups
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}