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In a simple model, where there is no auxiliary variable, and a Stratified Simple Random Sample was taken from the population, we can calculate the Bayes Linear Estimator for the individuals of each strata of the population with the BLE_SSRS() function, which receives the following parameters:
data(BigCity)
end <- dim(BigCity)[1]
s <- seq(from = 1, to = end, by = 1)
set.seed(3)
samp <- sample(s, size = 10000, replace = FALSE)
ordered_samp <- sort(samp)
BigCity_red <- BigCity[ordered_samp,]
Rural <- BigCity_red[which(BigCity_red$Zone == "Rural"),]
Rural_Exp <- Rural$Expenditure
length(Rural_Exp)
#> [1] 4757
Rural_ys <- sample(Rural_Exp, size = 30, replace = FALSE)
Urban <- BigCity_red[which(BigCity_red$Zone == "Urban"),]
Urban_Exp <- Urban$Expenditure
length(Urban_Exp)
#> [1] 5243
Urban_ys <- sample(Urban_Exp, size = 30, replace = FALSE)
The real expenditure means will be the values we want to estimate. In this example we know their real values:
Our design-based estimator for the mean will be the sample mean for each strata:
Applying the prior information about the population we can get a better estimate, especially in cases when only a small sample is available:
ys <- c(Rural_ys, Urban_ys)
h <- c(30,30)
N <- c(length(Rural_Exp), length(Urban_Exp))
m <- c(280, 420)
v=c(4*(10.1^4), 10.1^5)
sigma = c(sqrt(4*10^4), sqrt(10^5))
Estimator <- BLE_SSRS(ys, h, N, m, v, sigma)
Our Bayes Linear Estimator for the mean expenditure of each strata:
Estimator$est.beta
#> Beta
#> 1 292.3850
#> 2 454.9716
Estimator$Vest.beta
#> V1 V2
#> 1 732.2238 0.000
#> 2 0.0000 2015.967
ys <- c(2,-1,1.5, 6,10, 8,8)
h <- c(3,2,2)
N <- c(5,5,3)
m <- c(0,9,8)
v <- c(3,8,1)
sigma <- c(1,2,0.5)
Estimator <- BLE_SSRS(ys, h, N, m, v, sigma)
Estimator
#> $est.beta
#> Beta
#> 1 0.7142857
#> 2 8.3333333
#> 3 8.0000000
#>
#> $Vest.beta
#> V1 V2 V3
#> 1 0.2857143 0.000000 0.0000000
#> 2 0.0000000 1.333333 0.0000000
#> 3 0.0000000 0.000000 0.1071429
#>
#> $est.mean
#> y_nots
#> 1 0.7142857
#> 2 0.7142857
#> 3 8.3333333
#> 4 8.3333333
#> 5 8.3333333
#> 6 8.0000000
#>
#> $Vest.mean
#> V1 V2 V3 V4 V5 V6
#> 1 1.2857143 0.2857143 0.000000 0.000000 0.000000 0.0000000
#> 2 0.2857143 1.2857143 0.000000 0.000000 0.000000 0.0000000
#> 3 0.0000000 0.0000000 5.333333 1.333333 1.333333 0.0000000
#> 4 0.0000000 0.0000000 1.333333 5.333333 1.333333 0.0000000
#> 5 0.0000000 0.0000000 1.333333 1.333333 5.333333 0.0000000
#> 6 0.0000000 0.0000000 0.000000 0.000000 0.000000 0.3571429
#>
#> $est.tot
#> [1] 68.92857
#>
#> $Vest.tot
#> [1] 27.5
y1 <- mean(c(2,-1,1.5))
y2 <- mean(c(6,10))
y3 <- mean(c(8,8))
ys <- c(y1, y2, y3)
h <- c(3,2,2)
N <- c(5,5,3)
m <- c(0,9,8)
v <- c(3,8,1)
sigma <- c(1,2,0.5)
Estimator <- BLE_SSRS(ys, h, N, m, v, sigma)
#> sample means informed instead of sample observations, parameter 'sigma' will be necessary
Estimator
#> $est.beta
#> Beta
#> 1 0.7142857
#> 2 8.3333333
#> 3 8.0000000
#>
#> $Vest.beta
#> V1 V2 V3
#> 1 0.2857143 0.000000 0.0000000
#> 2 0.0000000 1.333333 0.0000000
#> 3 0.0000000 0.000000 0.1071429
#>
#> $est.mean
#> y_nots
#> 1 0.7142857
#> 2 0.7142857
#> 3 8.3333333
#> 4 8.3333333
#> 5 8.3333333
#> 6 8.0000000
#>
#> $Vest.mean
#> V1 V2 V3 V4 V5 V6
#> 1 1.2857143 0.2857143 0.000000 0.000000 0.000000 0.0000000
#> 2 0.2857143 1.2857143 0.000000 0.000000 0.000000 0.0000000
#> 3 0.0000000 0.0000000 5.333333 1.333333 1.333333 0.0000000
#> 4 0.0000000 0.0000000 1.333333 5.333333 1.333333 0.0000000
#> 5 0.0000000 0.0000000 1.333333 1.333333 5.333333 0.0000000
#> 6 0.0000000 0.0000000 0.000000 0.000000 0.000000 0.3571429
#>
#> $est.tot
#> [1] 68.92857
#>
#> $Vest.tot
#> [1] 27.5
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They may not be fully stable and should be used with caution. We make no claims about them.