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R/lieberson.R
In ndi: Neighborhood Deprivation Indices
Defines functions
lieberson
Documented in
lieberson
#' Isolation Index based on Lieberson (1981) and Bell (1954)
#'
#' Compute the aspatial Isolation Index (Lieberson) of a selected racial or ethnic subgroup(s) and U.S. geographies.
#'
#' @param geo_large Character string specifying the larger geographical unit of the data. The default is counties \code{geo_large = 'county'}.
#' @param geo_small Character string specifying the smaller geographical unit of the data. The default is census tracts \code{geo_small = 'tract'}.
#' @param year Numeric. The year to compute the estimate. The default is 2020, and the years 2009 onward are currently available.
#' @param subgroup Character string specifying the racial or ethnic subgroup(s). See Details for available choices.
#' @param omit_NAs Logical. If FALSE, will compute index for a larger geographical unit only if all of its smaller geographical units have values. The default is TRUE.
#' @param quiet Logical. If TRUE, will display messages about potential missing census information. The default is FALSE.
#' @param ... Arguments passed to \code{\link[tidycensus]{get_acs}} to select state, county, and other arguments for census characteristics
#'
#' @details This function will compute the aspatial Isolation Index (_xPx\*_) of selected racial or ethnic subgroups and U.S. geographies for a specified geographical extent (e.g., the entire U.S. or a single state) based on Lieberson (1981; ISBN-13:978-1-032-53884-6) and Bell (1954) \doi{10.2307/2574118}. This function provides the computation of _xPx\*_ for any of the U.S. Census Bureau race or ethnicity subgroups (including Hispanic and non-Hispanic individuals).
#'
#' The function uses the \code{\link[tidycensus]{get_acs}} function to obtain U.S. Census Bureau 5-year American Community Survey characteristics used for the aspatial computation. The yearly estimates are available for 2009 onward when ACS-5 data are available (2010 onward for \code{geo_large = 'cbsa'} and 2011 onward for \code{geo_large = 'place'}, \code{geo_large = 'csa'}, or \code{geo_large = 'metro'}) but may be available from other U.S. Census Bureau surveys. The twenty racial or ethnic subgroups (U.S. Census Bureau definitions) are:
#' \itemize{
#' \item \strong{B03002_002}: not Hispanic or Latino \code{'NHoL'}
#' \item \strong{B03002_003}: not Hispanic or Latino, white alone \code{'NHoLW'}
#' \item \strong{B03002_004}: not Hispanic or Latino, Black or African American alone \code{'NHoLB'}
#' \item \strong{B03002_005}: not Hispanic or Latino, American Indian and Alaska Native alone \code{'NHoLAIAN'}
#' \item \strong{B03002_006}: not Hispanic or Latino, Asian alone \code{'NHoLA'}
#' \item \strong{B03002_007}: not Hispanic or Latino, Native Hawaiian and Other Pacific Islander alone \code{'NHoLNHOPI'}
#' \item \strong{B03002_008}: not Hispanic or Latino, Some other race alone \code{'NHoLSOR'}
#' \item \strong{B03002_009}: not Hispanic or Latino, Two or more races \code{'NHoLTOMR'}
#' \item \strong{B03002_010}: not Hispanic or Latino, Two races including Some other race \code{'NHoLTRiSOR'}
#' \item \strong{B03002_011}: not Hispanic or Latino, Two races excluding Some other race, and three or more races \code{'NHoLTReSOR'}
#' \item \strong{B03002_012}: Hispanic or Latino \code{'HoL'}
#' \item \strong{B03002_013}: Hispanic or Latino, white alone \code{'HoLW'}
#' \item \strong{B03002_014}: Hispanic or Latino, Black or African American alone \code{'HoLB'}
#' \item \strong{B03002_015}: Hispanic or Latino, American Indian and Alaska Native alone \code{'HoLAIAN'}
#' \item \strong{B03002_016}: Hispanic or Latino, Asian alone \code{'HoLA'}
#' \item \strong{B03002_017}: Hispanic or Latino, Native Hawaiian and Other Pacific Islander alone \code{'HoLNHOPI'}
#' \item \strong{B03002_018}: Hispanic or Latino, Some other race alone \code{'HoLSOR'}
#' \item \strong{B03002_019}: Hispanic or Latino, Two or more races \code{'HoLTOMR'}
#' \item \strong{B03002_020}: Hispanic or Latino, Two races including Some other race \code{'HoLTRiSOR'}
#' \item \strong{B03002_021}: Hispanic or Latino, Two races excluding Some other race, and three or more races \code{'HoLTReSOR'}
#' }
#'
#' Use the internal \code{state} and \code{county} arguments within the \code{\link[tidycensus]{get_acs}} function to specify geographic extent of the data output.
#'
#' _xPx\*_ is some measure of the probability that a member of one subgroup(s) will meet or interact with a member of their subgroup(s) with higher values signifying higher probability of interaction (less isolation). _xPx\*_ can range in value from 0 to 1.
#'
#' Larger geographical units available include states \code{geo_large = 'state'}, counties \code{geo_large = 'county'}, census tracts \code{geo_large = 'tract'}, census-designated places \code{geo_large = 'place'}, core-based statistical areas \code{geo_large = 'cbsa'}, combined statistical areas \code{geo_large = 'csa'}, and metropolitan divisions \code{geo_large = 'metro'}. Smaller geographical units available include, counties \code{geo_small = 'county'}, census tracts \code{geo_small = 'tract'}, and census block groups \code{geo_small = 'cbg'}. If a larger geographical unit is comprised of only one smaller geographical unit (e.g., a U.S county contains only one census tract), then the _xPx\*_ value returned is NA. If the larger geographical unit is census-designated places \code{geo_large = 'place'}, core-based statistical areas \code{geo_large = 'cbsa'}, combined statistical areas \code{geo_large = 'csa'}, or metropolitan divisions \code{geo_large = 'metro'}, only the smaller geographical units completely within a larger geographical unit are considered in the _xPx\*_ computation (see internal \code{\link[sf]{st_within}} function for more information) and recommend specifying all states within which the interested larger geographical unit are located using the internal \code{state} argument to ensure all appropriate smaller geographical units are included in the _xPx\*_ computation.
#'
#' @return An object of class 'list'. This is a named list with the following components:
#'
#' \describe{
#' \item{\code{xpx_star}}{An object of class 'tbl' for the GEOID, name, and _xPx\*_ at specified larger census geographies.}
#' \item{\code{xpx_star_data}}{An object of class 'tbl' for the raw census values at specified smaller census geographies.}
#' \item{\code{missing}}{An object of class 'tbl' of the count and proportion of missingness for each census variable used to compute _xPx\*_.}
#' }
#'
#' @seealso \code{\link[tidycensus]{get_acs}} for additional arguments for geographic extent selection (i.e., \code{state} and \code{county}).
#' @seealso Other isolation indices: \code{\link{anthopolos}}, \code{\link{bemanian_beyer}}, \code{\link{morgan_massey}}, \code{\link{white}}
#' @seealso Interaction indices: \code{\link{bell}}, \code{\link{morgan_denton}}
#'
#' @references Lieberson, S (1981). "An Asymmetrical Approach to Segregation." Pp. 61-82 in \emph{Ethnic Segregation in Cities}, edited by Peach, C, Robinson, V, & Smith, S. 1st Ed. London:Croom Helm. ISBN-13:978-1-032-53884-6
#' @references Bell, W (1954) A probability model for the measurement of ecological segregation. \emph{Social Forces}, 32(4):357-364. \doi{10.2307/2574118}
#' @references Massey, DS, & Denton, NA (1988) The Dimensions of Residential Segregation. \emph{Social Forces}, 67(1):281-315. \doi{10.1093/sf/67.2.281}
#'
#' @import dplyr
#' @importFrom sf st_drop_geometry st_within
#' @importFrom stats complete.cases
#' @importFrom stringr str_trim
#' @importFrom tidycensus get_acs
#' @importFrom tidyr pivot_longer separate
#' @importFrom tigris combined_statistical_areas core_based_statistical_areas metro_divisions places
#' @importFrom utils stack
#' @export
#'
#' @examples
#' \dontrun{
#' # Wrapped in \dontrun{} because these examples require a Census API key.
#'
#' # Interaction (a measure of exposure)
#' ## of non-Hispanic Black vs. non-Hispanic white populations
#' ## in census tracts within counties of Georgia, U.S.A. (2020)
#' bell(
#' geo_large = 'county',
#' geo_small = 'tract',
#' state = 'GA',
#' year = 2020,
#' subgroup = 'NHoLB'
#' )
#'
#' }
#'
lieberson <- function(geo_large = 'county',
geo_small = 'tract',
year = 2020,
subgroup,
omit_NAs = TRUE,
quiet = FALSE,
...) {
# Check arguments
match.arg(geo_large, choices = c('state', 'county', 'tract', 'place', 'cbsa', 'csa', 'metro'))
match.arg(geo_small, choices = c('county', 'tract', 'cbg', 'block group'))
stopifnot(is.numeric(year), year >= 2009) # all variables available 2009 onward
match.arg(
subgroup,
several.ok = TRUE,
choices = c(
'NHoL',
'NHoLW',
'NHoLB',
'NHoLAIAN',
'NHoLA',
'NHoLNHOPI',
'NHoLSOR',
'NHoLTOMR',
'NHoLTRiSOR',
'NHoLTReSOR',
'HoL',
'HoLW',
'HoLB',
'HoLAIAN',
'HoLA',
'HoLNHOPI',
'HoLSOR',
'HoLTOMR',
'HoLTRiSOR',
'HoLTReSOR'
)
)
# Select census variables
vars <- c(
TotalPop = 'B03002_001',
NHoL = 'B03002_002',
NHoLW = 'B03002_003',
NHoLB = 'B03002_004',
NHoLAIAN = 'B03002_005',
NHoLA = 'B03002_006',
NHoLNHOPI = 'B03002_007',
NHoLSOR = 'B03002_008',
NHoLTOMR = 'B03002_009',
NHoLTRiSOR = 'B03002_010',
NHoLTReSOR = 'B03002_011',
HoL = 'B03002_012',
HoLW = 'B03002_013',
HoLB = 'B03002_014',
HoLAIAN = 'B03002_015',
HoLA = 'B03002_016',
HoLNHOPI = 'B03002_017',
HoLSOR = 'B03002_018',
HoLTOMR = 'B03002_019',
HoLTRiSOR = 'B03002_020',
HoLTReSOR = 'B03002_021'
)
selected_vars <- vars[c('TotalPop', subgroup)]
out_names <- names(selected_vars) # save for output
in_subgroup <- paste0(subgroup, 'E')
# Acquire xPx* variables and sf geometries
out_dat <- suppressMessages(suppressWarnings(
tidycensus::get_acs(
geography = geo_small,
year = year,
output = 'wide',
variables = selected_vars,
geometry = TRUE,
keep_geo_vars = TRUE,
...
)
))
# Format output
if (geo_small == 'county') {
out_dat <- out_dat %>%
tidyr::separate(NAME.y, into = c('county', 'state'), sep = ',')
}
if (geo_small == 'tract') {
out_dat <- out_dat %>%
tidyr::separate(NAME.y, into = c('tract', 'county', 'state'), sep = ',') %>%
dplyr::mutate(tract = gsub('[^0-9\\.]', '', tract))
}
if (geo_small == 'cbg' | geo_small == 'block group') {
out_dat <- out_dat %>%
tidyr::separate(NAME.y, into = c('cbg', 'tract', 'county', 'state'), sep = ',') %>%
dplyr::mutate(
tract = gsub('[^0-9\\.]', '', tract),
cbg = gsub('[^0-9\\.]', '', cbg)
)
}
# Grouping IDs for xPx* computation
if (geo_large == 'state') {
out_dat <- out_dat %>%
dplyr::mutate(
oid = STATEFP,
state = stringr::str_trim(state)
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'county') {
out_dat <- out_dat %>%
dplyr::mutate(
oid = paste0(STATEFP, COUNTYFP),
state = stringr::str_trim(state),
county = stringr::str_trim(county)
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'tract') {
out_dat <- out_dat %>%
dplyr::mutate(
oid = paste0(STATEFP, COUNTYFP, TRACTCE),
state = stringr::str_trim(state),
county = stringr::str_trim(county)
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'place') {
stopifnot(is.numeric(year), year >= 2011) # Places only available 2011 onward
lgeom <- suppressMessages(suppressWarnings(tigris::places(
year = year, state = unique(out_dat$state))
))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 4] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
place = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 5] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'cbsa') {
stopifnot(is.numeric(year), year >= 2010) # CBSAs only available 2010 onward
lgeom <- suppressMessages(suppressWarnings(tigris::core_based_statistical_areas(year = year)))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 3] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
cbsa = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 4] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'csa') {
stopifnot(is.numeric(year), year >= 2011) # CSAs only available 2011 onward
lgeom <- suppressMessages(suppressWarnings(tigris::combined_statistical_areas(year = year)))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 2] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
csa = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 3] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'metro') {
stopifnot(is.numeric(year), year >= 2011) # Metropolitan Divisions only available 2011 onward
lgeom <- suppressMessages(suppressWarnings(tigris::metro_divisions(year = year)))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 4] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
metro = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 5] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
# Count of racial or ethnic subgroup populations
## Count of racial or ethnic comparison subgroup population
if (length(in_subgroup) == 1) {
out_dat <- out_dat %>%
dplyr::mutate(subgroup = .[, in_subgroup])
} else {
out_dat <- out_dat %>%
dplyr::mutate(subgroup = rowSums(.[, in_subgroup]))
}
# Compute xPx*
## From Lieberson (1981) in ISBN-13:978-1-032-53884-6
## _{x}P_{x}^* = \sum_{i=1}^{k} \left ( \frac{x_{i}}{X}\right )\left ( \frac{x_{i}}{n_{i}}\right )
## Where for k geographical units i:
## X denotes the total number of subgroup population in study (reference) area
## x_{i} denotes the number of subgroup population X in geographical unit i
## n_{i} denotes the total population of geographical unit i
## Compute
out_tmp <- out_dat %>%
.[.$oid != 'NANA', ] %>%
split(., f = list(.$oid)) %>%
lapply(., FUN = xpx_star_fun, omit_NAs = omit_NAs) %>%
utils::stack(.) %>%
dplyr::mutate(
xPx_star = values,
oid = ind
) %>%
dplyr::select(xPx_star, oid)
# Warning for missingness of census characteristics
missingYN <- out_dat[, c('TotalPopE', in_subgroup)]
names(missingYN) <- out_names
missingYN <- missingYN %>%
tidyr::pivot_longer(
cols = dplyr::everything(),
names_to = 'variable',
values_to = 'val'
) %>%
dplyr::group_by(variable) %>%
dplyr::summarise(
total = dplyr::n(),
n_missing = sum(is.na(val)),
percent_missing = paste0(round(mean(is.na(val)) * 100, 2), ' %')
)
if (quiet == FALSE) {
# Warning for missing census data
if (sum(missingYN$n_missing) > 0) {
message('Warning: Missing census data')
}
}
# Format output
out <- out_dat %>%
dplyr::left_join(out_tmp, by = dplyr::join_by(oid))
if (geo_large == 'state') {
out <- out %>%
dplyr::select(oid, state, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, state, xPx_star)
}
if (geo_large == 'county') {
out <- out %>%
dplyr::select(oid, state, county, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, state, county, xPx_star)
}
if (geo_large == 'tract') {
out <- out %>%
dplyr::select(oid, state, county, tract, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, state, county, tract, xPx_star)
}
if (geo_large == 'place') {
out <- out %>%
dplyr::select(oid, place, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, place, xPx_star)
}
if (geo_large == 'cbsa') {
out <- out %>%
dplyr::select(oid, cbsa, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, cbsa, xPx_star)
}
if (geo_large == 'csa') {
out <- out %>%
dplyr::select(oid, csa, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, csa, xPx_star)
}
if (geo_large == 'metro') {
out <- out %>%
dplyr::select(oid, metro, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, metro, xPx_star)
}
out <- out %>%
.[.$GEOID != 'NANA', ] %>%
dplyr::filter(!is.na(GEOID)) %>%
dplyr::distinct(GEOID, .keep_all = TRUE) %>%
dplyr::arrange(GEOID) %>%
dplyr::as_tibble()
out_dat <- out_dat %>%
dplyr::arrange(GEOID) %>%
dplyr::as_tibble()
out <- list(xpx_star = out, xpx_star_data = out_dat, missing = missingYN)
return(out)
}
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Defines functions lieberson
Documented in lieberson
#' Isolation Index based on Lieberson (1981) and Bell (1954)
#'
#' Compute the aspatial Isolation Index (Lieberson) of a selected racial or ethnic subgroup(s) and U.S. geographies.
#'
#' @param geo_large Character string specifying the larger geographical unit of the data. The default is counties \code{geo_large = 'county'}.
#' @param geo_small Character string specifying the smaller geographical unit of the data. The default is census tracts \code{geo_small = 'tract'}.
#' @param year Numeric. The year to compute the estimate. The default is 2020, and the years 2009 onward are currently available.
#' @param subgroup Character string specifying the racial or ethnic subgroup(s). See Details for available choices.
#' @param omit_NAs Logical. If FALSE, will compute index for a larger geographical unit only if all of its smaller geographical units have values. The default is TRUE.
#' @param quiet Logical. If TRUE, will display messages about potential missing census information. The default is FALSE.
#' @param ... Arguments passed to \code{\link[tidycensus]{get_acs}} to select state, county, and other arguments for census characteristics
#'
#' @details This function will compute the aspatial Isolation Index (_xPx\*_) of selected racial or ethnic subgroups and U.S. geographies for a specified geographical extent (e.g., the entire U.S. or a single state) based on Lieberson (1981; ISBN-13:978-1-032-53884-6) and Bell (1954) \doi{10.2307/2574118}. This function provides the computation of _xPx\*_ for any of the U.S. Census Bureau race or ethnicity subgroups (including Hispanic and non-Hispanic individuals).
#'
#' The function uses the \code{\link[tidycensus]{get_acs}} function to obtain U.S. Census Bureau 5-year American Community Survey characteristics used for the aspatial computation. The yearly estimates are available for 2009 onward when ACS-5 data are available (2010 onward for \code{geo_large = 'cbsa'} and 2011 onward for \code{geo_large = 'place'}, \code{geo_large = 'csa'}, or \code{geo_large = 'metro'}) but may be available from other U.S. Census Bureau surveys. The twenty racial or ethnic subgroups (U.S. Census Bureau definitions) are:
#' \itemize{
#' \item \strong{B03002_002}: not Hispanic or Latino \code{'NHoL'}
#' \item \strong{B03002_003}: not Hispanic or Latino, white alone \code{'NHoLW'}
#' \item \strong{B03002_004}: not Hispanic or Latino, Black or African American alone \code{'NHoLB'}
#' \item \strong{B03002_005}: not Hispanic or Latino, American Indian and Alaska Native alone \code{'NHoLAIAN'}
#' \item \strong{B03002_006}: not Hispanic or Latino, Asian alone \code{'NHoLA'}
#' \item \strong{B03002_007}: not Hispanic or Latino, Native Hawaiian and Other Pacific Islander alone \code{'NHoLNHOPI'}
#' \item \strong{B03002_008}: not Hispanic or Latino, Some other race alone \code{'NHoLSOR'}
#' \item \strong{B03002_009}: not Hispanic or Latino, Two or more races \code{'NHoLTOMR'}
#' \item \strong{B03002_010}: not Hispanic or Latino, Two races including Some other race \code{'NHoLTRiSOR'}
#' \item \strong{B03002_011}: not Hispanic or Latino, Two races excluding Some other race, and three or more races \code{'NHoLTReSOR'}
#' \item \strong{B03002_012}: Hispanic or Latino \code{'HoL'}
#' \item \strong{B03002_013}: Hispanic or Latino, white alone \code{'HoLW'}
#' \item \strong{B03002_014}: Hispanic or Latino, Black or African American alone \code{'HoLB'}
#' \item \strong{B03002_015}: Hispanic or Latino, American Indian and Alaska Native alone \code{'HoLAIAN'}
#' \item \strong{B03002_016}: Hispanic or Latino, Asian alone \code{'HoLA'}
#' \item \strong{B03002_017}: Hispanic or Latino, Native Hawaiian and Other Pacific Islander alone \code{'HoLNHOPI'}
#' \item \strong{B03002_018}: Hispanic or Latino, Some other race alone \code{'HoLSOR'}
#' \item \strong{B03002_019}: Hispanic or Latino, Two or more races \code{'HoLTOMR'}
#' \item \strong{B03002_020}: Hispanic or Latino, Two races including Some other race \code{'HoLTRiSOR'}
#' \item \strong{B03002_021}: Hispanic or Latino, Two races excluding Some other race, and three or more races \code{'HoLTReSOR'}
#' }
#'
#' Use the internal \code{state} and \code{county} arguments within the \code{\link[tidycensus]{get_acs}} function to specify geographic extent of the data output.
#'
#' _xPx\*_ is some measure of the probability that a member of one subgroup(s) will meet or interact with a member of their subgroup(s) with higher values signifying higher probability of interaction (less isolation). _xPx\*_ can range in value from 0 to 1.
#'
#' Larger geographical units available include states \code{geo_large = 'state'}, counties \code{geo_large = 'county'}, census tracts \code{geo_large = 'tract'}, census-designated places \code{geo_large = 'place'}, core-based statistical areas \code{geo_large = 'cbsa'}, combined statistical areas \code{geo_large = 'csa'}, and metropolitan divisions \code{geo_large = 'metro'}. Smaller geographical units available include, counties \code{geo_small = 'county'}, census tracts \code{geo_small = 'tract'}, and census block groups \code{geo_small = 'cbg'}. If a larger geographical unit is comprised of only one smaller geographical unit (e.g., a U.S county contains only one census tract), then the _xPx\*_ value returned is NA. If the larger geographical unit is census-designated places \code{geo_large = 'place'}, core-based statistical areas \code{geo_large = 'cbsa'}, combined statistical areas \code{geo_large = 'csa'}, or metropolitan divisions \code{geo_large = 'metro'}, only the smaller geographical units completely within a larger geographical unit are considered in the _xPx\*_ computation (see internal \code{\link[sf]{st_within}} function for more information) and recommend specifying all states within which the interested larger geographical unit are located using the internal \code{state} argument to ensure all appropriate smaller geographical units are included in the _xPx\*_ computation.
#'
#' @return An object of class 'list'. This is a named list with the following components:
#'
#' \describe{
#' \item{\code{xpx_star}}{An object of class 'tbl' for the GEOID, name, and _xPx\*_ at specified larger census geographies.}
#' \item{\code{xpx_star_data}}{An object of class 'tbl' for the raw census values at specified smaller census geographies.}
#' \item{\code{missing}}{An object of class 'tbl' of the count and proportion of missingness for each census variable used to compute _xPx\*_.}
#' }
#'
#' @seealso \code{\link[tidycensus]{get_acs}} for additional arguments for geographic extent selection (i.e., \code{state} and \code{county}).
#' @seealso Other isolation indices: \code{\link{anthopolos}}, \code{\link{bemanian_beyer}}, \code{\link{morgan_massey}}, \code{\link{white}}
#' @seealso Interaction indices: \code{\link{bell}}, \code{\link{morgan_denton}}
#'
#' @references Lieberson, S (1981). "An Asymmetrical Approach to Segregation." Pp. 61-82 in \emph{Ethnic Segregation in Cities}, edited by Peach, C, Robinson, V, & Smith, S. 1st Ed. London:Croom Helm. ISBN-13:978-1-032-53884-6
#' @references Bell, W (1954) A probability model for the measurement of ecological segregation. \emph{Social Forces}, 32(4):357-364. \doi{10.2307/2574118}
#' @references Massey, DS, & Denton, NA (1988) The Dimensions of Residential Segregation. \emph{Social Forces}, 67(1):281-315. \doi{10.1093/sf/67.2.281}
#'
#' @import dplyr
#' @importFrom sf st_drop_geometry st_within
#' @importFrom stats complete.cases
#' @importFrom stringr str_trim
#' @importFrom tidycensus get_acs
#' @importFrom tidyr pivot_longer separate
#' @importFrom tigris combined_statistical_areas core_based_statistical_areas metro_divisions places
#' @importFrom utils stack
#' @export
#'
#' @examples
#' \dontrun{
#' # Wrapped in \dontrun{} because these examples require a Census API key.
#'
#' # Interaction (a measure of exposure)
#' ## of non-Hispanic Black vs. non-Hispanic white populations
#' ## in census tracts within counties of Georgia, U.S.A. (2020)
#' bell(
#' geo_large = 'county',
#' geo_small = 'tract',
#' state = 'GA',
#' year = 2020,
#' subgroup = 'NHoLB'
#' )
#'
#' }
#'
lieberson <- function(geo_large = 'county',
geo_small = 'tract',
year = 2020,
subgroup,
omit_NAs = TRUE,
quiet = FALSE,
...) {
# Check arguments
match.arg(geo_large, choices = c('state', 'county', 'tract', 'place', 'cbsa', 'csa', 'metro'))
match.arg(geo_small, choices = c('county', 'tract', 'cbg', 'block group'))
stopifnot(is.numeric(year), year >= 2009) # all variables available 2009 onward
match.arg(
subgroup,
several.ok = TRUE,
choices = c(
'NHoL',
'NHoLW',
'NHoLB',
'NHoLAIAN',
'NHoLA',
'NHoLNHOPI',
'NHoLSOR',
'NHoLTOMR',
'NHoLTRiSOR',
'NHoLTReSOR',
'HoL',
'HoLW',
'HoLB',
'HoLAIAN',
'HoLA',
'HoLNHOPI',
'HoLSOR',
'HoLTOMR',
'HoLTRiSOR',
'HoLTReSOR'
)
)
# Select census variables
vars <- c(
TotalPop = 'B03002_001',
NHoL = 'B03002_002',
NHoLW = 'B03002_003',
NHoLB = 'B03002_004',
NHoLAIAN = 'B03002_005',
NHoLA = 'B03002_006',
NHoLNHOPI = 'B03002_007',
NHoLSOR = 'B03002_008',
NHoLTOMR = 'B03002_009',
NHoLTRiSOR = 'B03002_010',
NHoLTReSOR = 'B03002_011',
HoL = 'B03002_012',
HoLW = 'B03002_013',
HoLB = 'B03002_014',
HoLAIAN = 'B03002_015',
HoLA = 'B03002_016',
HoLNHOPI = 'B03002_017',
HoLSOR = 'B03002_018',
HoLTOMR = 'B03002_019',
HoLTRiSOR = 'B03002_020',
HoLTReSOR = 'B03002_021'
)
selected_vars <- vars[c('TotalPop', subgroup)]
out_names <- names(selected_vars) # save for output
in_subgroup <- paste0(subgroup, 'E')
# Acquire xPx* variables and sf geometries
out_dat <- suppressMessages(suppressWarnings(
tidycensus::get_acs(
geography = geo_small,
year = year,
output = 'wide',
variables = selected_vars,
geometry = TRUE,
keep_geo_vars = TRUE,
...
)
))
# Format output
if (geo_small == 'county') {
out_dat <- out_dat %>%
tidyr::separate(NAME.y, into = c('county', 'state'), sep = ',')
}
if (geo_small == 'tract') {
out_dat <- out_dat %>%
tidyr::separate(NAME.y, into = c('tract', 'county', 'state'), sep = ',') %>%
dplyr::mutate(tract = gsub('[^0-9\\.]', '', tract))
}
if (geo_small == 'cbg' | geo_small == 'block group') {
out_dat <- out_dat %>%
tidyr::separate(NAME.y, into = c('cbg', 'tract', 'county', 'state'), sep = ',') %>%
dplyr::mutate(
tract = gsub('[^0-9\\.]', '', tract),
cbg = gsub('[^0-9\\.]', '', cbg)
)
}
# Grouping IDs for xPx* computation
if (geo_large == 'state') {
out_dat <- out_dat %>%
dplyr::mutate(
oid = STATEFP,
state = stringr::str_trim(state)
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'county') {
out_dat <- out_dat %>%
dplyr::mutate(
oid = paste0(STATEFP, COUNTYFP),
state = stringr::str_trim(state),
county = stringr::str_trim(county)
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'tract') {
out_dat <- out_dat %>%
dplyr::mutate(
oid = paste0(STATEFP, COUNTYFP, TRACTCE),
state = stringr::str_trim(state),
county = stringr::str_trim(county)
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'place') {
stopifnot(is.numeric(year), year >= 2011) # Places only available 2011 onward
lgeom <- suppressMessages(suppressWarnings(tigris::places(
year = year, state = unique(out_dat$state))
))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 4] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
place = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 5] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'cbsa') {
stopifnot(is.numeric(year), year >= 2010) # CBSAs only available 2010 onward
lgeom <- suppressMessages(suppressWarnings(tigris::core_based_statistical_areas(year = year)))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 3] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
cbsa = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 4] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'csa') {
stopifnot(is.numeric(year), year >= 2011) # CSAs only available 2011 onward
lgeom <- suppressMessages(suppressWarnings(tigris::combined_statistical_areas(year = year)))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 2] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
csa = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 3] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
if (geo_large == 'metro') {
stopifnot(is.numeric(year), year >= 2011) # Metropolitan Divisions only available 2011 onward
lgeom <- suppressMessages(suppressWarnings(tigris::metro_divisions(year = year)))
wlgeom <- sf::st_within(out_dat, lgeom)
out_dat <- out_dat %>%
dplyr::mutate(
oid = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 4] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist(),
metro = lapply(wlgeom, function(x) {
tmp <- lgeom[x, 5] %>% sf::st_drop_geometry()
lapply(tmp, function(x) { if (length(x) == 0) NA else x })
}) %>%
unlist()
) %>%
sf::st_drop_geometry()
}
# Count of racial or ethnic subgroup populations
## Count of racial or ethnic comparison subgroup population
if (length(in_subgroup) == 1) {
out_dat <- out_dat %>%
dplyr::mutate(subgroup = .[, in_subgroup])
} else {
out_dat <- out_dat %>%
dplyr::mutate(subgroup = rowSums(.[, in_subgroup]))
}
# Compute xPx*
## From Lieberson (1981) in ISBN-13:978-1-032-53884-6
## _{x}P_{x}^* = \sum_{i=1}^{k} \left ( \frac{x_{i}}{X}\right )\left ( \frac{x_{i}}{n_{i}}\right )
## Where for k geographical units i:
## X denotes the total number of subgroup population in study (reference) area
## x_{i} denotes the number of subgroup population X in geographical unit i
## n_{i} denotes the total population of geographical unit i
## Compute
out_tmp <- out_dat %>%
.[.$oid != 'NANA', ] %>%
split(., f = list(.$oid)) %>%
lapply(., FUN = xpx_star_fun, omit_NAs = omit_NAs) %>%
utils::stack(.) %>%
dplyr::mutate(
xPx_star = values,
oid = ind
) %>%
dplyr::select(xPx_star, oid)
# Warning for missingness of census characteristics
missingYN <- out_dat[, c('TotalPopE', in_subgroup)]
names(missingYN) <- out_names
missingYN <- missingYN %>%
tidyr::pivot_longer(
cols = dplyr::everything(),
names_to = 'variable',
values_to = 'val'
) %>%
dplyr::group_by(variable) %>%
dplyr::summarise(
total = dplyr::n(),
n_missing = sum(is.na(val)),
percent_missing = paste0(round(mean(is.na(val)) * 100, 2), ' %')
)
if (quiet == FALSE) {
# Warning for missing census data
if (sum(missingYN$n_missing) > 0) {
message('Warning: Missing census data')
}
}
# Format output
out <- out_dat %>%
dplyr::left_join(out_tmp, by = dplyr::join_by(oid))
if (geo_large == 'state') {
out <- out %>%
dplyr::select(oid, state, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, state, xPx_star)
}
if (geo_large == 'county') {
out <- out %>%
dplyr::select(oid, state, county, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, state, county, xPx_star)
}
if (geo_large == 'tract') {
out <- out %>%
dplyr::select(oid, state, county, tract, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, state, county, tract, xPx_star)
}
if (geo_large == 'place') {
out <- out %>%
dplyr::select(oid, place, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, place, xPx_star)
}
if (geo_large == 'cbsa') {
out <- out %>%
dplyr::select(oid, cbsa, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, cbsa, xPx_star)
}
if (geo_large == 'csa') {
out <- out %>%
dplyr::select(oid, csa, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, csa, xPx_star)
}
if (geo_large == 'metro') {
out <- out %>%
dplyr::select(oid, metro, xPx_star) %>%
unique(.) %>%
dplyr::mutate(GEOID = oid) %>%
dplyr::select(GEOID, metro, xPx_star)
}
out <- out %>%
.[.$GEOID != 'NANA', ] %>%
dplyr::filter(!is.na(GEOID)) %>%
dplyr::distinct(GEOID, .keep_all = TRUE) %>%
dplyr::arrange(GEOID) %>%
dplyr::as_tibble()
out_dat <- out_dat %>%
dplyr::arrange(GEOID) %>%
dplyr::as_tibble()
out <- list(xpx_star = out, xpx_star_data = out_dat, missing = missingYN)
return(out)
}
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