VE_Jk_B_RegCoI_Hajek: The Berger (2007) unequal probability jackknife variance...
In samplingVarEst: Sampling Variance Estimation
VE.Jk.B.RegCoI.Hajek R Documentation
The Berger (2007) unequal probability jackknife variance estimator for the estimator of the intercept regression coefficient using the Hajek point estimator
Description
Computes the Berger (2007) unequal probability jackknife variance estimator for the estimator of the intercept regression coefficient using the Hajek (1971) point estimator.
Usage
VE.Jk.B.RegCoI.Hajek(VecY.s, VecX.s, VecPk.s)
Arguments
VecY.s
vector of the variable of interest Y; its length is equal to n, the sample size. Its length has to be the same as that of VecPk.s and VecX.s. There must not be missing values.
VecX.s
vector of the variable of interest X; its length is equal to n, the sample size. Its length has to be the same as that of VecPk.s and VecY.s. There must not be missing values.
VecPk.s
vector of the first-order inclusion probabilities; its length is equal to n, the sample size. Values in VecPk.s must be greater than zero and less than or equal to one. There must not be missing values.
Details
From Linear Regression Analysis, for an imposed population model
y=α + β x
the population intercept regression coefficient α, assuming that the population size N is unknown (see Sarndal et al., 1992, Sec. 5.10), can be estimated by:
\hat{α}_{Hajek} = \hat{\bar{y}}_{Hajek} - \frac{∑_{k\in s} w_k (y_k - \hat{\bar{y}}_{Hajek})(x_k - \hat{\bar{x}}_{Hajek})}{∑_{k\in s} w_k (x_k - \hat{\bar{x}}_{Hajek})^2} \hat{\bar{x}}_{Hajek}
where \hat{\bar{y}}_{Hajek} and \hat{\bar{x}}_{Hajek} are the Hajek (1971) point estimators of the population means \bar{y} = N^{-1} ∑_{k\in U} y_k and \bar{x} = N^{-1} ∑_{k\in U} x_k, respectively,
\hat{\bar{y}}_{Hajek} = \frac{∑_{k\in s} w_k y_k}{∑_{k\in s} w_k}
\hat{\bar{x}}_{Hajek} = \frac{∑_{k\in s} w_k x_k}{∑_{k\in s} w_k}
and w_k=1/π_k with π_k denoting the inclusion probability of the k-th element in the sample s. The variance of \hat{α}_{Hajek} can be estimated by the Berger (2007) unequal probability jackknife variance estimator (implemented by the current function):
\hat{V}(\hat{α}_{Hajek}) = ∑_{k\in s} \frac{n}{n-1}(1-π_k) ≤ft(\varepsilon_k - \hat{B}\right)^{2}
where
\hat{B} = \frac{∑_{k\in s}(1-π_k) \varepsilon_k}{∑_{k\in s}(1-π_k)}
and
\varepsilon_k = ≤ft(1-\tilde{w}_k\right) ≤ft(\hat{α}_{Hajek}-\hat{α}_{Hajek(k)}\right)
with
\tilde{w}_k = \frac{w_k}{∑_{l\in s} w_l}
and where \hat{α}_{Hajek(k)} has the same functional form as \hat{α}_{Hajek} but omitting the k-th element from the sample s.
Note that this variance estimator implicitly utilises the Hajek (1964) approximations that are designed for large-entropy sampling designs, large samples, and large populations, i.e., care should be taken with highly-stratified samples, e.g. Berger (2005).
Value
The function returns a value for the estimated variance.
Author(s)
Emilio Lopez Escobar.
References
Berger, Y. G. (2005) Variance estimation with highly stratified sampling designs with unequal probabilities. Australian & New Zealand Journal of Statistics, 47, 365–373.
Berger, Y. G. (2007) A jackknife variance estimator for unistage stratified samples with unequal probabilities. Biometrika 94, 953–964.
Hajek, J. (1964) Asymptotic theory of rejective sampling with varying probabilities from a finite population. The Annals of Mathematical Statistics, 35, 4, 1491–1523.
Hajek, J. (1971) Comment on An essay on the logical foundations of survey sampling by Basu, D. in Foundations of Statistical Inference (Godambe, V.P. and Sprott, D.A. eds.), p. 236. Holt, Rinehart and Winston.
Sarndal, C.-E. and Swensson, B. and Wretman, J. (1992) Model Assisted Survey Sampling. Springer-Verlag, Inc.
See Also
VE.Jk.B.RegCo.Hajek
VE.Jk.Tukey.RegCoI.Hajek
VE.Jk.CBS.HT.RegCoI.Hajek
VE.Jk.CBS.SYG.RegCoI.Hajek
VE.Jk.EB.SW2.RegCoI.Hajek
Examples
data(oaxaca) #Loads the Oaxaca municipalities dataset
pik.U <- Pk.PropNorm.U(373, oaxaca$HOMES00) #Reconstructs the 1st order incl. probs.
s <- oaxaca$sHOMES00 #Defines the sample to be used
y1 <- oaxaca$POP10 #Defines the variable of interest y1
y2 <- oaxaca$POPMAL10 #Defines the variable of interest y2
x <- oaxaca$HOMES10 #Defines the variable of interest x
#Computes the var. est. of the intercept reg. coeff. point estimator using y1
VE.Jk.B.RegCoI.Hajek(y1[s==1], x[s==1], pik.U[s==1])
#Computes the var. est. of the intercept reg. coeff. point estimator using y2
VE.Jk.B.RegCoI.Hajek(y2[s==1], x[s==1], pik.U[s==1])
samplingVarEst documentation built on Jan. 14, 2023, 5:08 p.m.
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The Berger (2007) unequal probability jackknife variance estimator for the estimator of the intercept regression coefficient using the Hajek point estimator
Description
Computes the Berger (2007) unequal probability jackknife variance estimator for the estimator of the intercept regression coefficient using the Hajek (1971) point estimator.
Usage
VE.Jk.B.RegCoI.Hajek(VecY.s, VecX.s, VecPk.s)
Arguments
VecY.s |
vector of the variable of interest Y; its length is equal to n, the sample size. Its length has to be the same as that of |
VecX.s |
vector of the variable of interest X; its length is equal to n, the sample size. Its length has to be the same as that of |
VecPk.s |
vector of the first-order inclusion probabilities; its length is equal to n, the sample size. Values in |
Details
From Linear Regression Analysis, for an imposed population model
y=α + β x
the population intercept regression coefficient α, assuming that the population size N is unknown (see Sarndal et al., 1992, Sec. 5.10), can be estimated by:
\hat{α}_{Hajek} = \hat{\bar{y}}_{Hajek} - \frac{∑_{k\in s} w_k (y_k - \hat{\bar{y}}_{Hajek})(x_k - \hat{\bar{x}}_{Hajek})}{∑_{k\in s} w_k (x_k - \hat{\bar{x}}_{Hajek})^2} \hat{\bar{x}}_{Hajek}
where \hat{\bar{y}}_{Hajek} and \hat{\bar{x}}_{Hajek} are the Hajek (1971) point estimators of the population means \bar{y} = N^{-1} ∑_{k\in U} y_k and \bar{x} = N^{-1} ∑_{k\in U} x_k, respectively,
\hat{\bar{y}}_{Hajek} = \frac{∑_{k\in s} w_k y_k}{∑_{k\in s} w_k}
\hat{\bar{x}}_{Hajek} = \frac{∑_{k\in s} w_k x_k}{∑_{k\in s} w_k}
and w_k=1/π_k with π_k denoting the inclusion probability of the k-th element in the sample s. The variance of \hat{α}_{Hajek} can be estimated by the Berger (2007) unequal probability jackknife variance estimator (implemented by the current function):
\hat{V}(\hat{α}_{Hajek}) = ∑_{k\in s} \frac{n}{n-1}(1-π_k) ≤ft(\varepsilon_k - \hat{B}\right)^{2}
where
\hat{B} = \frac{∑_{k\in s}(1-π_k) \varepsilon_k}{∑_{k\in s}(1-π_k)}
and
\varepsilon_k = ≤ft(1-\tilde{w}_k\right) ≤ft(\hat{α}_{Hajek}-\hat{α}_{Hajek(k)}\right)
with
\tilde{w}_k = \frac{w_k}{∑_{l\in s} w_l}
and where \hat{α}_{Hajek(k)} has the same functional form as \hat{α}_{Hajek} but omitting the k-th element from the sample s. Note that this variance estimator implicitly utilises the Hajek (1964) approximations that are designed for large-entropy sampling designs, large samples, and large populations, i.e., care should be taken with highly-stratified samples, e.g. Berger (2005).
Value
The function returns a value for the estimated variance.
Author(s)
Emilio Lopez Escobar.
References
Berger, Y. G. (2005) Variance estimation with highly stratified sampling designs with unequal probabilities. Australian & New Zealand Journal of Statistics, 47, 365–373.
Berger, Y. G. (2007) A jackknife variance estimator for unistage stratified samples with unequal probabilities. Biometrika 94, 953–964.
Hajek, J. (1964) Asymptotic theory of rejective sampling with varying probabilities from a finite population. The Annals of Mathematical Statistics, 35, 4, 1491–1523.
Hajek, J. (1971) Comment on An essay on the logical foundations of survey sampling by Basu, D. in Foundations of Statistical Inference (Godambe, V.P. and Sprott, D.A. eds.), p. 236. Holt, Rinehart and Winston.
Sarndal, C.-E. and Swensson, B. and Wretman, J. (1992) Model Assisted Survey Sampling. Springer-Verlag, Inc.
See Also
VE.Jk.B.RegCo.HajekVE.Jk.Tukey.RegCoI.HajekVE.Jk.CBS.HT.RegCoI.HajekVE.Jk.CBS.SYG.RegCoI.HajekVE.Jk.EB.SW2.RegCoI.Hajek
Examples
data(oaxaca) #Loads the Oaxaca municipalities dataset pik.U <- Pk.PropNorm.U(373, oaxaca$HOMES00) #Reconstructs the 1st order incl. probs. s <- oaxaca$sHOMES00 #Defines the sample to be used y1 <- oaxaca$POP10 #Defines the variable of interest y1 y2 <- oaxaca$POPMAL10 #Defines the variable of interest y2 x <- oaxaca$HOMES10 #Defines the variable of interest x #Computes the var. est. of the intercept reg. coeff. point estimator using y1 VE.Jk.B.RegCoI.Hajek(y1[s==1], x[s==1], pik.U[s==1]) #Computes the var. est. of the intercept reg. coeff. point estimator using y2 VE.Jk.B.RegCoI.Hajek(y2[s==1], x[s==1], pik.U[s==1])
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