survey (version 3.9-1)

brrweights: Compute replicate weights

Description

Compute replicate weights from a survey design. These functions are usually called from as.svrepdesign rather than directly by the user.

Usage

brrweights(strata, psu, match = NULL,
              small = c("fail","split","merge"),
              large = c("split", "merge", "fail"),
              fay.rho=0, only.weights=FALSE,
              compress=TRUE, hadamard.matrix=NULL)
jk1weights(psu,fpc=NULL,
              fpctype=c("population","fraction","correction"),
              compress=TRUE)
jknweights(strata,psu, fpc=NULL,
              fpctype=c("population","fraction","correction"),
              compress=TRUE,
              lonely.psu=getOption("survey.lonely.psu"))

Arguments

strata
Stratum identifiers
psu
PSU (cluster) identifier
match
Optional variable to use in matching.
small
How to handle strata with only one PSU
large
How to handle strata with more than two PSUs
fpc
Optional population (stratum) size or finite population correction
fpctype
How fpc is coded.
fay.rho
Parameter for Fay's extended BRR method
only.weights
If TRUE return only the matrix of replicate weights
compress
If TRUE, store the replicate weights in compressed form
hadamard.matrix
Optional user-supplied Hadamard matrix for brrweights
lonely.psu
Handling of non-certainty single-PSU strata

Value

  • For brrweights with only.weights=FALSE a list with elements
  • weightstwo-column matrix indicating the weight for each half-stratum in one particular set of split samples
  • wstrataNew stratum variable incorporating merged or split strata
  • strataOriginal strata for distinct PSUs
  • psuDistinct PSUs
  • npairsDimension of Hadamard matrix used in BRR construction
  • samplerfunction returning replicate weights
  • compressIndicates whether the sampler returns per PSU or per observation weights
  • For jk1weights and jknweights a data frame of replicate weights and the scale and rscale arguments to svrVar.

Details

JK1 and JKn are jackknife schemes for unstratified and stratified designs respectively. The finite population correction may be specified as a single number, a vector with one entry per stratum, or a vector with one entry per observation (constant within strata). When fpc is a vector with one entry per stratum it may not have names that differ from the stratum identifiers (it may have no names, in which case it must be in the same order as unique(strata)). To specify population stratum sizes use fpctype="population", to specify sampling fractions use fpctype="fraction" and to specify the correction directly use fpctype="correction" The only reason not to use compress=TRUE is that it is new and there is a greater possibility of bugs. It reduces the number of rows of the replicate weights matrix from the number of observations to the number of PSUs. In BRR variance estimation each stratum is split in two to give half-samples. Balanced replicated weights are needed, where observations in two different strata end up in the same half stratum as often as in different half-strata.BRR, strictly speaking, is defined only when each stratum has exactly two PSUs. A stratum with one PSU can be merged with another such stratum, or can be split to appear in both half samples with half weight. The latter approach is appropriate for a PSU that was deterministically sampled. A stratum with more than two PSUs can be split into multiple smaller strata each with two PSUs or the PSUs can be merged to give two superclusters within the stratum. When merging small strata or grouping PSUs in large strata the match variable is used to sort PSUs before merging, to give approximate matching on this variable. If you want more control than this you should probably construct your own weights using the Hadamard matrices produced by hadamard

References

Levy and Lemeshow "Sampling of Populations". Wiley. Shao and Tu "The Jackknife and Bootstrap". Springer.

See Also

hadamard, as.svrepdesign, svrVar, surveyoptions

Examples

Run this code
data(scd)
scdnofpc<-svydesign(data=scd, prob=~1, id=~ambulance, strata=~ESA,
nest=TRUE)

## convert to BRR replicate weights
scd2brr <- as.svrepdesign(scdnofpc, type="BRR")
svymean(~alive, scd2brr)
svyratio(~alive, ~arrests, scd2brr)

## with user-supplied hadamard matrix
scd2brr1 <- as.svrepdesign(scdnofpc, type="BRR", hadamard.matrix=paley(11))
svymean(~alive, scd2brr1)
svyratio(~alive, ~arrests, scd2brr1)

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