Model based inference using ranked set samples
Section 2. Sampling designs
We
consider RSS sampling designs from a super population model to draw statistical
inference in a finite population setting. Let
be the characteristic of interest. The copies
of
are considered as independent identically
distributed (iid) random variables from a super population. Basic assumption
for this super population model can be stated as
The subscript
in model (2.1) is used to highlight that the
mean and variance are computed based on a super population model, not the
randomization distribution as in Ozturk (2016b). In this super population
model,
and
represent unknown infinite population
parameters.
In
super population model, a particular realization,
of random variables
from model (2.1), is considered as a finite
population. Let
denotes this finite population. Ranked set
sample is constructed from
Without loss of generality, we assume that
are ordered values of
where
is the
largest value of
in
Throughout the paper,
and
are used to denote the set and cycle sizes,
respectively.
To
construct a ranked set sample, one selects a set of
experimental units,
at random from
and ranks them based on their
values in an increasing magnitude without
actual measurement. Ranking process can be performed either using visual
inspection or some auxiliary variables and hence subjected to ranking error.
The unit that corresponds to the smallest
is identified and measured where the square
bracket in the subscript, [1], denotes the rank of the smallest unit (rank 1)
in the set
The remaining unmeasured units are denoted
with
After
is measured, none of the
units in the set
are returned to the population. One then
selects another set of
experimental units at random from the
remaining population
and ranks them without measurement. This time,
the unit that corresponds to the second smallest
is identified and measured in
This process is continued until a simple
random sample of size
is taken from the reduced population
and the
smallest unit is identified and measured in
the set
This is called a cycle. A cycle selects
disjoint sets, each of size
and only measures
units. The remaining
units are used only for ranking purposes. The
cycles are repeated
times to yield a ranked set sample of size
units. A ranked set sample can then be represented
as
where only
are measured. The other values are used to
obtain the rank of the measured values. Units in sets
and
are all independent if either
or
but the units in
are all correlated since they are ranked in the same set.
Under model (2.1), means, variances and covariances of judgment order
statistics are given by
It
should be noted that since all sets are disjoint no units can be used more than
once in any one of the sets. Hence all sample units are distinct. Since the
sets are independently ranked
are mutually independent. Observations having the
same rank
are identically distributed.
Estimator
of the population mean
based on RSS data in equation (2.2) can be
defined as follows.
It
can be immediately observed that the estimator
is model unbiased. In other words, under the
model (2.1),
where
We
now consider the mean square prediction error (MSPE) of the estimator
under model (2.1)
Since the predictor
is model unbiased for
the mean square prediction error (MSPE) of
is the same as
Theorem 1 Let
be a ranked set sample
from a finite population
Under a super
population model in equation (2.1), the mean square prediction error of the
estimator
is given by
We
note that expression on equation (2.4) is very similar to the sample variance
of an infinite population RSS sample. Only difference is due to the coefficient
In infinite population setting the fraction
in equation (2.4) becomes
Hence,
is the finite population correction (fpc)
factor for the variance of RSS sample mean. If the sample size is not small in
comparison with the population size
the fpc,
makes a correction on the variance of an RSS sample mean.
This correction would be substantial if
is relatively large with respect to
If
is small, fpc is close to 1 and the impact of
finite population correction factor is minimal.
Corollary 1 Assume that
and
increase in such a way that the ratio
approaches to a limit at
i. If
converges to a
simple form
ii. if
which is the
same as the variance of the sample mean of a balanced ranked set sample in an
infinite population setting,
iii. if
is strictly
positive, then
The
corollary indicates that when sample and population sizes grow at a certain
rate, variance of sample mean of an RSS
sample in a finite population setting reduces
to simple form. If
is strictly positive, variance of an RSS
sample mean is smaller than the variance of an RSS sample mean in an infinite
population setting.
ISSN : 1492-0921
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