A generalization of inverse probability weighting
Section 7. Simulation results
In this simulation, estimators from the preceding
section will be compared to the ordinary inverse probability estimator and the
ordinary calibrated estimator. A population of 2,000 individuals grouped into
1,000 two-person households was generated. Persons
and
for
belong to the same household. A variable of
interest
takes the value 1 to represent a vaccinated
person, and it takes the value 0 to represent an unvaccinated person. To
simulate how vaccination status can be correlated within household, the method
of Lunn and Davies (1998) was used to generate pairs of correlated Bernoulli
variables with a probability of 0.7 of a value of 1 and a correlation of 0.8.
The actual population generated has 254 households where neither person is
vaccinated, 660 households where both are vaccinated, 44 households where only
the person with an odd label is vaccinated, and 42 households where only the
person with an even label is vaccinated. The total number of persons vaccinated
is
for a vaccination rate of 0.703. The
correlation between persons of the same household is
The population was sampled 10,000 times. Each household
was sampled independently; the probability of
selecting both units was 0.05, the probability of selecting only unit
was 0.10, and the probability of selecting
only unit
was 0.05. Thus, for each sample, the
probabilities of inclusion were
and
This means
in (1.2) was chosen to not be zero. This is
because when
is zero,
is a somewhat obvious choice: it is an inverse
probability estimator based on pairs where the pair is given a value of
if only unit
is sampled, a value of
if only unit
is sampled, and a value of
if both units are sampled. Combined with
calibration, it is an obvious competitor to the ordinary calibration estimator.
Why not base the estimator on pairs in this way, rather than units, if there is
a strong correlation between units of a pair? When
is zero, it is also true that
It is interesting to find out how
compares when
is not zero. For each sample, eight estimators
of the total were calculated: the inverse probability estimator, the ordinary
calibrated estimator, the generalization of the inverse probability estimator
and its calibrated version, the modified generalized inverse probability
estimator and its calibrated version, and finally the alternative estimator and
its calibrated version. For the generalized and modified generalized
estimators, including their calibrated versions,
with
was used, as explained in the examples of the
preceding section. The simple closed-form formulae of that section can thus be
used. For the calibration,
with
and
yields
The average total and the variance over the
10,000 repetitions are given in Table 7.1.
Table 7.1
Simulation results comparing eight estimators
Table summary
This table displays the results of Simulation results comparing eight estimators
. The information is grouped by Estimator and lower bounds (appearing as row headers), Total and Variance (appearing as column headers).
| Estimator and lower bounds |
Total |
Variance |
| Inverse probability |
1,406.60 |
13,326 |
| Calibrated inverse probability |
1,407.38 |
3,856 |
| Generalized inverse probability |
1,406.41 |
11,226 |
| Calibrated generalized inverse probability |
1,407.08 |
3,419 |
| Modified generalized inverse probability |
1,406.37 |
16,337 |
| Calibrated modified generalized inverse probability |
1,406.68 |
4,932 |
| Alternative |
1,406.61 |
12,447 |
| Calibrated alternative |
1,407.12 |
3,697 |
| Generalized Godambe-Joshi lower bound (
0.8) |
|
3,408 |
| Generalized Godambe-Joshi lower bound (
) |
|
3,360 |
All eight estimators are either unbiased or
asymptotically unbiased, so as expected, the observed bias of each estimator is
negligible, since the real population total is 1,406.
The observed variances show that only the four
calibrated estimators have reasonable variances. With the sampling plan used
for this simulation, only the calibrated estimators can estimate the known
population total with zero variance.
The calibrated generalized inverse probability
estimator, with a variance of 3,419, performs best. This despite being
calculated assuming that the correlation between the units of a pair is one. It
should be remembered that the calibrated inverse probability estimator, with a
variance of 3,856, is a special case of the calibrated generalized inverse probability
estimator, but it is computed assuming that the correlation between the units
of a pair is zero. The calibrated alternative estimator, which contrary to the
other estimators, has been defined only for a household size of 2, has a
variance somewhere in between that of the calibrated versions of the inverse
probability and generalized inverse probability estimators. Finally, the
calibrated modified generalized estimator had the highest variance of the four
calibrated estimators.
The generalized Godambe-Joshi lower bound with the
variance matrix,
of the model
used to generate
is 3,408. This is the asymptotic variance that
could be expected of the calibrated generalized estimator, if it had been
calculated with a matrix
based on the correct model
where the correlation between units of a pair
is 0.8. If
is defined as in the preceding section, and
is the generalized Godambe-Joshi lower bound
for the positive definite variance matrix
then the limit as
of
is 3,360. This is the variance that could be
expected of the generalized calibration estimator, if the correlation between
units of a same pair was one.
ISSN : 1492-0921
Editorial policy
Survey Methodology publishes articles dealing with various aspects of statistical development relevant to a statistical agency, such as design issues in the context of practical constraints, use of different data sources and collection techniques, total survey error, survey evaluation, research in survey methodology, time series analysis, seasonal adjustment, demographic studies, data integration, estimation and data analysis methods, and general survey systems development. The emphasis is placed on the development and evaluation of specific methodologies as applied to data collection or the data themselves. All papers will be refereed. However, the authors retain full responsibility for the contents of their papers and opinions expressed are not necessarily those of the Editorial Board or of Statistics Canada.
Submission of Manuscripts
Survey Methodology is published twice a year in electronic format. Authors are invited to submit their articles in English or French in electronic form, preferably in Word to the Editor, (statcan.smj-rte.statcan@canada.ca, Statistics Canada, 150 Tunney’s Pasture Driveway, Ottawa, Ontario, Canada, K1A 0T6). For formatting instructions, please see the guidelines provided in the journal and on the web site (www.statcan.gc.ca/SurveyMethodology).
Note of appreciation
Canada owes the success of its statistical system to a long-standing partnership between Statistics Canada, the citizens of Canada, its businesses, governments and other institutions. Accurate and timely statistical information could not be produced without their continued co-operation and goodwill.
Standards of service to the public
Statistics Canada is committed to serving its clients in a prompt, reliable and courteous manner. To this end, the Agency has developed standards of service which its employees observe in serving its clients.
Copyright
Published by authority of the Minister responsible for Statistics Canada.
© His Majesty the King in Right of Canada as represented by the Minister of Industry, 2022
Use of this publication is governed by the Statistics Canada Open Licence Agreement.
Catalogue No. 12-001-X
Frequency: Semi-annual
Ottawa