tests/testthat/test-extract-svyjdivdec.R
In DjalmaPessoa/convey: Income Concentration Analysis with Complex Survey Samples
# load libraries
library(survey)
library(laeken)
# library( vardpoor )
# return test context
context("svyjdivdec decomposition output survey.design and svyrep.design")
### test 2: income data from eusilc --- data.frame-backed design object
# collect and format data
data(eusilc)
names(eusilc) <- tolower(names(eusilc))
# set up survey design objects
des_eusilc <-
svydesign(
ids = ~ rb030 ,
strata = ~ db040 ,
weights = ~ rb050 ,
data = eusilc
)
des_eusilc_rep <-
as.svrepdesign(des_eusilc , type = "bootstrap" , replicates = 50)
# prepare for convey
des_eusilc <- convey_prep(des_eusilc)
des_eusilc_rep <- convey_prep(des_eusilc_rep)
# filter postive incomes
des_eusilc <- subset(des_eusilc , eqincome > 0)
des_eusilc_rep <- subset(des_eusilc_rep , eqincome > 0)
# calculate estimates
a1 <-
svyjdivdec(
~ eqincome ,
des_eusilc ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
a2 <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
a2.nocov <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = FALSE
)
b1 <-
svyjdivdec(
~ eqincome ,
des_eusilc_rep ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE
)
b2 <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc_rep ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE
)
b2.nocov <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc_rep ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = FALSE
)
d1 <-
svyjdiv(~ eqincome ,
des_eusilc ,
deff = TRUE ,
linearized = TRUE)
d2 <-
svyby( ~ eqincome ,
~ rb090,
des_eusilc ,
svyjdiv ,
deff = TRUE)
# calculate auxilliary tests statistics
cv_diff1 <- max(abs(cv(a1) - cv(b1)))
se_diff2 <- max(abs(SE(a2) - SE(b2)) , na.rm = TRUE)
# perform tests
test_that("output svyjdivdec" , {
expect_is(coef(a1) , "numeric")
expect_is(coef(a2) , "numeric")
expect_is(coef(b1) , "numeric")
expect_is(coef(b2) , "numeric")
expect_equal(coef(a1) , coef(b1))
expect_equal(coef(a2) , coef(b2))
# expect_lte( cv_diff1 , (coef(a1)[[1]]) * 0.05 ) # the difference between CVs should be less than 5% of the coefficient, otherwise manually set it
expect_lte(se_diff2 , max(coef(a2)) * 0.05) # the difference between CVs should be less than 10% of the maximum coefficient, otherwise manually set it
expect_equal(sum(confint(a2)[, 1] <= coef(a2)) , length(coef(a2)))
expect_equal(sum(confint(a2)[, 2] >= coef(a2)) , length(coef(a2)))
expect_equal(sum(confint(b2)[, 1] <= coef(b2)) , length(coef(b2)))
expect_equal(sum(confint(b2)[, 2] >= coef(b2)) , length(coef(b2)))
expect_equal(coef(a1)[[1]] , coef(d1)[[1]])
expect_equal(as.numeric(coef(a2)[1:2]) , as.numeric(coef(d2)))
# check equality of linearized variables
expect_equal(attr(a1 , "linearized") , attr(b1 , "linearized"))
expect_equal(attr(a1 , "index") , attr(b1 , "index"))
# check equality vcov diagonals
expect_warning(expect_equal(diag(vcov(a2)) , diag(vcov(a2.nocov))))
expect_warning(expect_equal(diag(vcov(b2)) , diag(vcov(b2.nocov))))
# compare with svyjdiv
expect_equal(coef(a1)[[1]] , coef(d1)[[1]])
expect_equal(SE(a1)[[1]] , SE(d1)[[1]])
expect_equal(as.numeric(attr(a1 , "linearized")[, 1, drop = FALSE]) , as.numeric(attr(d1 , "linearized")))
expect_equal(as.numeric(SE(a2)[, 1]) , as.numeric(SE(d2)))
})
### test 2: income data from eusilc --- database-backed design object
# perform tests
test_that("database svyjdivdec", {
# skip test on cran
skip_on_cran()
# load libraries
library(RSQLite)
library(DBI)
# set-up database
dbfile <- tempfile()
conn <- dbConnect(RSQLite::SQLite() , dbfile)
dbWriteTable(conn , 'eusilc' , eusilc)
# database-backed design
dbd_eusilc <-
svydesign(
ids = ~ rb030 ,
strata = ~ db040 ,
weights = ~ rb050 ,
data = "eusilc",
dbname = dbfile,
dbtype = "SQLite"
)
# prepare for convey
dbd_eusilc <- convey_prep(dbd_eusilc)
# filter postive incomes
dbd_eusilc <- subset(dbd_eusilc , eqincome > 0)
# calculate estimates
c1 <-
svyjdivdec(
~ eqincome ,
dbd_eusilc ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
c2 <-
svyby(
~ eqincome ,
~ rb090,
dbd_eusilc ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
# remove table and close connection to database
dbRemoveTable(conn , 'eusilc')
dbDisconnect(conn)
# peform tests
expect_equal(coef(a1) , coef(c1))
expect_equal(coef(a2) , coef(c2)[match(names(coef(c2)) , names(coef(a2)))])
expect_equal(SE(a1) , SE(c1))
expect_equal(SE(a2) , SE(c2)[2:1 , ])
expect_equal(deff(a1) , deff(c1))
expect_equal(deff(a2) , deff(c2)[2:1 , ])
# check equality of linearized variables
expect_equal(colSums(attr(a1 , "linearized")) , colSums(attr(c1 , "linearized")))
expect_equal(colSums(attr(a1 , "influence")) , colSums(attr(c1 , "influence")))
expect_equal(colSums(attr(a2 , "influence")) , colSums(attr(c2 , "influence")))
# expect_equal(attr(c1 , "index") , attr(a1 , "index"))
})
# calculate estimates
sub_des <-
svyjdivdec(
~ eqincome ,
design = subset(des_eusilc , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
sby_des <-
svyby(
~ eqincome,
by = ~ rb090,
design = des_eusilc,
FUN = svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
sub_rep <-
svyjdivdec(
~ eqincome ,
design = subset(des_eusilc_rep , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE
)
sby_rep <-
svyby(
~ eqincome,
by = ~ rb090,
design = des_eusilc_rep,
FUN = svyjdivdec ,
epsilon = this.epsilon ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE
)
# perform tests
test_that("subsets equal svyby", {
# domain vs svyby: coefficients must be equal
expect_equal(as.numeric(coef(sub_des)) , as.numeric(coef(sby_des[1,])))
expect_equal(as.numeric(coef(sub_rep)) , as.numeric(coef(sby_rep[1,])))
# domain vs svyby: SEs must be equal
expect_equal(as.numeric(SE(sub_des)) , as.numeric(SE(sby_des[1,])))
expect_equal(as.numeric(SE(sub_rep)) , as.numeric(SE(sby_rep[1,])))
# domain vs svyby and svydesign vs svyrepdesign:
# coefficients should match across svydesign
expect_equal(as.numeric(coef(sub_des)) , as.numeric(coef(sby_rep[1,])))
# domain vs svyby and svydesign vs svyrepdesign:
# coefficients of variation should be within five percent
cv_diff <- max(abs(cv(sub_des) - cv(sby_rep)[1,]))
expect_lte(cv_diff , .20)
# check equality of linearized variables
expect_equal(attr(sub_des , "linearized") , attr(sub_rep , "linearized"))
# check equality of variances
expect_equal(vcov(sub_des)[1] , vcov(sby_des)[1, 1])
expect_equal(vcov(sub_rep)[1] , vcov(sby_rep)[1, 1])
})
### test 4: compare subsetted objects to svyby objects
# compare database-backed designs to non-database-backed designs
test_that("dbi subsets equal non-dbi subsets", {
skip_on_cran()
# load libraries
library(RSQLite)
library(DBI)
# set up database
dbfile <- tempfile()
conn <- dbConnect(RSQLite::SQLite() , dbfile)
dbWriteTable(conn , 'eusilc' , eusilc)
# create database-backed design (with survey design information)
dbd_eusilc <-
svydesign(
ids = ~ rb030 ,
strata = ~ db040 ,
weights = ~ rb050 ,
data = "eusilc",
dbname = dbfile,
dbtype = "SQLite"
)
# create a hacky database-backed svrepdesign object
# mirroring des_eusilc_rep
dbd_eusilc_rep <-
svrepdesign(
weights = ~ rb050,
repweights = attr(des_eusilc_rep , "full_design")$repweights ,
scale = attr(des_eusilc_rep , "full_design")$scale ,
rscales = attr(des_eusilc_rep , "full_design")$rscales ,
type = "bootstrap" ,
data = "eusilc" ,
dbtype = "SQLite" ,
dbname = dbfile ,
combined.weights = FALSE
)
# prepare for convey
dbd_eusilc <- convey_prep(dbd_eusilc)
dbd_eusilc_rep <- convey_prep(dbd_eusilc_rep)
# filter postive incomes
dbd_eusilc <- subset(dbd_eusilc , eqincome > 0)
dbd_eusilc_rep <- subset(dbd_eusilc_rep , eqincome > 0)
# calculate estimates
sub_dbd <-
svyjdivdec(
~ eqincome ,
design = subset(dbd_eusilc , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
sby_dbd <-
svyby(
~ eqincome,
by = ~ rb090,
design = dbd_eusilc,
FUN = svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
sub_dbr <-
svyjdivdec(
~ eqincome ,
design = subset(dbd_eusilc_rep , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE
)
sby_dbr <-
svyby(
~ eqincome,
by = ~ rb090,
design = dbd_eusilc_rep,
FUN = svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE
)
# remove table and disconnect from database
dbRemoveTable(conn , 'eusilc')
dbDisconnect(conn)
# perform tests
expect_equal(coef(sub_des) , coef(sub_dbd))
expect_equal(coef(sub_rep) , coef(sub_dbr))
expect_equal(SE(sub_des) , SE(sub_dbd))
expect_equal(SE(sub_rep) , SE(sub_dbr))
expect_equal(deff(sub_des) , deff(sub_dbd))
expect_equal(deff(sub_rep) , deff(sub_dbr))
expect_equal(vcov(sub_des) , vcov(sub_dbd))
expect_equal(vcov(sub_rep) , vcov(sub_dbr))
# compare database-backed subsetted objects to database-backed svyby objects
# dbi subsets equal dbi svyby
expect_equal(as.numeric(coef(sub_dbd)) , as.numeric(coef(sby_dbd[2,])))
expect_equal(as.numeric(coef(sub_dbr)) , as.numeric(coef(sby_dbr[2,])))
expect_equal(as.numeric(SE(sub_dbd)) , as.numeric(SE(sby_dbd[2,])))
expect_equal(as.numeric(SE(sub_dbr)) , as.numeric(SE(sby_dbr[2,])))
expect_equal(vcov(sub_dbd) , vcov(sub_des))
expect_equal(vcov(sub_dbr) , vcov(sub_rep))
# compare equality of linearized variables
expect_equal(colSums(attr(sub_dbd , "linearized")) , colSums(attr(sub_dbr , "linearized")))
expect_equal(colSums(attr(sub_dbd , "linearized")) , colSums(attr(sub_des , "linearized")))
expect_equal(attr(sub_dbr , "linearized") , attr(sub_rep , "linearized"))
# compare equality of influence functions
expect_equal(colSums(attr(sub_dbd , "influence")) , colSums(attr(sub_des , "influence")))
expect_equal(attr(sub_dbr , "influence") , attr(sub_rep , "influence"))
# compare equality of indices
# expect_equal(attr(sub_dbd , "index") , attr(sub_dbr , "index"))
# expect_equal(attr(sub_dbd , "index") , attr(sub_des , "index"))
expect_equal(attr(sub_dbr , "index") , attr(sub_rep , "index"))
})
DjalmaPessoa/convey documentation built on Oct. 15, 2024, 10:30 p.m.
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# load libraries
library(survey)
library(laeken)
# library( vardpoor )
# return test context
context("svyjdivdec decomposition output survey.design and svyrep.design")
### test 2: income data from eusilc --- data.frame-backed design object
# collect and format data
data(eusilc)
names(eusilc) <- tolower(names(eusilc))
# set up survey design objects
des_eusilc <-
svydesign(
ids = ~ rb030 ,
strata = ~ db040 ,
weights = ~ rb050 ,
data = eusilc
)
des_eusilc_rep <-
as.svrepdesign(des_eusilc , type = "bootstrap" , replicates = 50)
# prepare for convey
des_eusilc <- convey_prep(des_eusilc)
des_eusilc_rep <- convey_prep(des_eusilc_rep)
# filter postive incomes
des_eusilc <- subset(des_eusilc , eqincome > 0)
des_eusilc_rep <- subset(des_eusilc_rep , eqincome > 0)
# calculate estimates
a1 <-
svyjdivdec(
~ eqincome ,
des_eusilc ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
a2 <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
a2.nocov <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = FALSE
)
b1 <-
svyjdivdec(
~ eqincome ,
des_eusilc_rep ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE
)
b2 <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc_rep ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE
)
b2.nocov <-
svyby(
~ eqincome ,
~ rb090,
des_eusilc_rep ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = FALSE
)
d1 <-
svyjdiv(~ eqincome ,
des_eusilc ,
deff = TRUE ,
linearized = TRUE)
d2 <-
svyby( ~ eqincome ,
~ rb090,
des_eusilc ,
svyjdiv ,
deff = TRUE)
# calculate auxilliary tests statistics
cv_diff1 <- max(abs(cv(a1) - cv(b1)))
se_diff2 <- max(abs(SE(a2) - SE(b2)) , na.rm = TRUE)
# perform tests
test_that("output svyjdivdec" , {
expect_is(coef(a1) , "numeric")
expect_is(coef(a2) , "numeric")
expect_is(coef(b1) , "numeric")
expect_is(coef(b2) , "numeric")
expect_equal(coef(a1) , coef(b1))
expect_equal(coef(a2) , coef(b2))
# expect_lte( cv_diff1 , (coef(a1)[[1]]) * 0.05 ) # the difference between CVs should be less than 5% of the coefficient, otherwise manually set it
expect_lte(se_diff2 , max(coef(a2)) * 0.05) # the difference between CVs should be less than 10% of the maximum coefficient, otherwise manually set it
expect_equal(sum(confint(a2)[, 1] <= coef(a2)) , length(coef(a2)))
expect_equal(sum(confint(a2)[, 2] >= coef(a2)) , length(coef(a2)))
expect_equal(sum(confint(b2)[, 1] <= coef(b2)) , length(coef(b2)))
expect_equal(sum(confint(b2)[, 2] >= coef(b2)) , length(coef(b2)))
expect_equal(coef(a1)[[1]] , coef(d1)[[1]])
expect_equal(as.numeric(coef(a2)[1:2]) , as.numeric(coef(d2)))
# check equality of linearized variables
expect_equal(attr(a1 , "linearized") , attr(b1 , "linearized"))
expect_equal(attr(a1 , "index") , attr(b1 , "index"))
# check equality vcov diagonals
expect_warning(expect_equal(diag(vcov(a2)) , diag(vcov(a2.nocov))))
expect_warning(expect_equal(diag(vcov(b2)) , diag(vcov(b2.nocov))))
# compare with svyjdiv
expect_equal(coef(a1)[[1]] , coef(d1)[[1]])
expect_equal(SE(a1)[[1]] , SE(d1)[[1]])
expect_equal(as.numeric(attr(a1 , "linearized")[, 1, drop = FALSE]) , as.numeric(attr(d1 , "linearized")))
expect_equal(as.numeric(SE(a2)[, 1]) , as.numeric(SE(d2)))
})
### test 2: income data from eusilc --- database-backed design object
# perform tests
test_that("database svyjdivdec", {
# skip test on cran
skip_on_cran()
# load libraries
library(RSQLite)
library(DBI)
# set-up database
dbfile <- tempfile()
conn <- dbConnect(RSQLite::SQLite() , dbfile)
dbWriteTable(conn , 'eusilc' , eusilc)
# database-backed design
dbd_eusilc <-
svydesign(
ids = ~ rb030 ,
strata = ~ db040 ,
weights = ~ rb050 ,
data = "eusilc",
dbname = dbfile,
dbtype = "SQLite"
)
# prepare for convey
dbd_eusilc <- convey_prep(dbd_eusilc)
# filter postive incomes
dbd_eusilc <- subset(dbd_eusilc , eqincome > 0)
# calculate estimates
c1 <-
svyjdivdec(
~ eqincome ,
dbd_eusilc ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
c2 <-
svyby(
~ eqincome ,
~ rb090,
dbd_eusilc ,
svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
# remove table and close connection to database
dbRemoveTable(conn , 'eusilc')
dbDisconnect(conn)
# peform tests
expect_equal(coef(a1) , coef(c1))
expect_equal(coef(a2) , coef(c2)[match(names(coef(c2)) , names(coef(a2)))])
expect_equal(SE(a1) , SE(c1))
expect_equal(SE(a2) , SE(c2)[2:1 , ])
expect_equal(deff(a1) , deff(c1))
expect_equal(deff(a2) , deff(c2)[2:1 , ])
# check equality of linearized variables
expect_equal(colSums(attr(a1 , "linearized")) , colSums(attr(c1 , "linearized")))
expect_equal(colSums(attr(a1 , "influence")) , colSums(attr(c1 , "influence")))
expect_equal(colSums(attr(a2 , "influence")) , colSums(attr(c2 , "influence")))
# expect_equal(attr(c1 , "index") , attr(a1 , "index"))
})
# calculate estimates
sub_des <-
svyjdivdec(
~ eqincome ,
design = subset(des_eusilc , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
sby_des <-
svyby(
~ eqincome,
by = ~ rb090,
design = des_eusilc,
FUN = svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
sub_rep <-
svyjdivdec(
~ eqincome ,
design = subset(des_eusilc_rep , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE
)
sby_rep <-
svyby(
~ eqincome,
by = ~ rb090,
design = des_eusilc_rep,
FUN = svyjdivdec ,
epsilon = this.epsilon ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE
)
# perform tests
test_that("subsets equal svyby", {
# domain vs svyby: coefficients must be equal
expect_equal(as.numeric(coef(sub_des)) , as.numeric(coef(sby_des[1,])))
expect_equal(as.numeric(coef(sub_rep)) , as.numeric(coef(sby_rep[1,])))
# domain vs svyby: SEs must be equal
expect_equal(as.numeric(SE(sub_des)) , as.numeric(SE(sby_des[1,])))
expect_equal(as.numeric(SE(sub_rep)) , as.numeric(SE(sby_rep[1,])))
# domain vs svyby and svydesign vs svyrepdesign:
# coefficients should match across svydesign
expect_equal(as.numeric(coef(sub_des)) , as.numeric(coef(sby_rep[1,])))
# domain vs svyby and svydesign vs svyrepdesign:
# coefficients of variation should be within five percent
cv_diff <- max(abs(cv(sub_des) - cv(sby_rep)[1,]))
expect_lte(cv_diff , .20)
# check equality of linearized variables
expect_equal(attr(sub_des , "linearized") , attr(sub_rep , "linearized"))
# check equality of variances
expect_equal(vcov(sub_des)[1] , vcov(sby_des)[1, 1])
expect_equal(vcov(sub_rep)[1] , vcov(sby_rep)[1, 1])
})
### test 4: compare subsetted objects to svyby objects
# compare database-backed designs to non-database-backed designs
test_that("dbi subsets equal non-dbi subsets", {
skip_on_cran()
# load libraries
library(RSQLite)
library(DBI)
# set up database
dbfile <- tempfile()
conn <- dbConnect(RSQLite::SQLite() , dbfile)
dbWriteTable(conn , 'eusilc' , eusilc)
# create database-backed design (with survey design information)
dbd_eusilc <-
svydesign(
ids = ~ rb030 ,
strata = ~ db040 ,
weights = ~ rb050 ,
data = "eusilc",
dbname = dbfile,
dbtype = "SQLite"
)
# create a hacky database-backed svrepdesign object
# mirroring des_eusilc_rep
dbd_eusilc_rep <-
svrepdesign(
weights = ~ rb050,
repweights = attr(des_eusilc_rep , "full_design")$repweights ,
scale = attr(des_eusilc_rep , "full_design")$scale ,
rscales = attr(des_eusilc_rep , "full_design")$rscales ,
type = "bootstrap" ,
data = "eusilc" ,
dbtype = "SQLite" ,
dbname = dbfile ,
combined.weights = FALSE
)
# prepare for convey
dbd_eusilc <- convey_prep(dbd_eusilc)
dbd_eusilc_rep <- convey_prep(dbd_eusilc_rep)
# filter postive incomes
dbd_eusilc <- subset(dbd_eusilc , eqincome > 0)
dbd_eusilc_rep <- subset(dbd_eusilc_rep , eqincome > 0)
# calculate estimates
sub_dbd <-
svyjdivdec(
~ eqincome ,
design = subset(dbd_eusilc , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE ,
influence = TRUE
)
sby_dbd <-
svyby(
~ eqincome,
by = ~ rb090,
design = dbd_eusilc,
FUN = svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE ,
influence = TRUE
)
sub_dbr <-
svyjdivdec(
~ eqincome ,
design = subset(dbd_eusilc_rep , rb090 == "male") ,
subgroup = ~ db040 ,
deff = TRUE ,
linearized = TRUE
)
sby_dbr <-
svyby(
~ eqincome,
by = ~ rb090,
design = dbd_eusilc_rep,
FUN = svyjdivdec ,
subgroup = ~ db040 ,
deff = TRUE ,
covmat = TRUE
)
# remove table and disconnect from database
dbRemoveTable(conn , 'eusilc')
dbDisconnect(conn)
# perform tests
expect_equal(coef(sub_des) , coef(sub_dbd))
expect_equal(coef(sub_rep) , coef(sub_dbr))
expect_equal(SE(sub_des) , SE(sub_dbd))
expect_equal(SE(sub_rep) , SE(sub_dbr))
expect_equal(deff(sub_des) , deff(sub_dbd))
expect_equal(deff(sub_rep) , deff(sub_dbr))
expect_equal(vcov(sub_des) , vcov(sub_dbd))
expect_equal(vcov(sub_rep) , vcov(sub_dbr))
# compare database-backed subsetted objects to database-backed svyby objects
# dbi subsets equal dbi svyby
expect_equal(as.numeric(coef(sub_dbd)) , as.numeric(coef(sby_dbd[2,])))
expect_equal(as.numeric(coef(sub_dbr)) , as.numeric(coef(sby_dbr[2,])))
expect_equal(as.numeric(SE(sub_dbd)) , as.numeric(SE(sby_dbd[2,])))
expect_equal(as.numeric(SE(sub_dbr)) , as.numeric(SE(sby_dbr[2,])))
expect_equal(vcov(sub_dbd) , vcov(sub_des))
expect_equal(vcov(sub_dbr) , vcov(sub_rep))
# compare equality of linearized variables
expect_equal(colSums(attr(sub_dbd , "linearized")) , colSums(attr(sub_dbr , "linearized")))
expect_equal(colSums(attr(sub_dbd , "linearized")) , colSums(attr(sub_des , "linearized")))
expect_equal(attr(sub_dbr , "linearized") , attr(sub_rep , "linearized"))
# compare equality of influence functions
expect_equal(colSums(attr(sub_dbd , "influence")) , colSums(attr(sub_des , "influence")))
expect_equal(attr(sub_dbr , "influence") , attr(sub_rep , "influence"))
# compare equality of indices
# expect_equal(attr(sub_dbd , "index") , attr(sub_dbr , "index"))
# expect_equal(attr(sub_dbd , "index") , attr(sub_des , "index"))
expect_equal(attr(sub_dbr , "index") , attr(sub_rep , "index"))
})
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