A generalization of inverse probability weighting
Section 3. The generalized calibration estimator
The sum of the weights of an estimator is an estimate of
the known population size, When the sampling plan is such that the sample
size is not fixed, the ordinary inverse probability estimator of the population
size will have a variance greater than zero. The sum of the weights of noted is often a worse estimator of the population
size than the sum of the weights of it will often vary, even when the sample size
is fixed. An estimator whose estimates of the population size vary, cannot be
seen as very reliable.
To fix the problem that the ordinary inverse probability
estimator experiences when the sample size is variable, calibration can be
used. The weights of are calibrated so that their sum equals the
population size, .
A similar fix can be made to the generalized estimator: The definition of will be expanded to include the possibility of
more calibration equations involving more auxiliary variables. The use of
calibration equations was presented in Deville and Särndal (1992).
With an auxiliary variable matrix
assumed to be of full rank and noting the weighted Euclidean norm of the vector the following problem is addressed:
Calibration Problem: Among the weight vectors
in
the range of i.e.,
non-sampled units should have a weight of 0, which minimize i.e.,
which “best” satisfy the calibration equations, seek one that minimizes
i.e., as
close as possible to the weights of where
and
are
positive definite matrices.
Weights, that satisfy the calibration equations, do not always exist, especially if the number
of equations, is high relative to the sample size. To
prepare for this eventuality, the matrix is at the statistician’s disposal for
specifying the relative importance of the calibration equations. The matrix specifies the relative importance given to
each unit when measuring the distance from This formulation of the calibration problem
generalizes that of Théberge (1999), where and were diagonal matrices, and the inverse
probability, or Horvitz-Thompson, weights were used instead of the generalized
inverse probability weights.
The solution to the calibration problem yields
where with
The estimator is asymptotically unbiased. Also, if in probability, then the bias and variance of are asymptotically the same as those of The rate at which will depend on the estimator and on the number of parameters in
The difference between and the ordinary calibration estimator, is simply the use of generalized inverse
probability weights to estimate the sum of the residues, rather than the usual
inverse probability weights. This was to be expected given that in one case we
are, in the calibration problem, seeking weights that minimize instead of weights that minimize where are the usual inverse probability weights.
The following result is proven in the Appendix: for any
, if is in the range of then the weighted sum of residuals, is zero. A vector is said to be in the range of a matrix is there exists a vector such that In particular, if the matrix is diagonal and written where is the diagonal matrix of the ordinary inverse
probability weights and
is an arbitrary positive diagonal
matrix, then with the result gives that is zero if is in the range of This is similar to result 6.5.1 of Särndal,
Swensson and Wretman (1992), for example, where is a vector of ones and the diagonal elements
of are variances.
It can be seen from the form of (3.1), that is also a regression estimator that uses a
model such that Despite the notation used in (3.2),
calibration estimators do not use models, instead there are calibration
equations. When viewed as a regression estimator, it is important to realize
that is asymptotically design unbiased, regardless
of the choice of the model parameter and regardless of the choice of the positive
definite matrix
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