Sampling design. types, methods, merits and demerits

Sampling Design
Presented by- Dr. Kapil Kumar
PG 1st
year
Deptt. of Community Medicine
MMIMSR,Mullana

A sample design is a definite plan for obtaining a sample from a given
population.
It refers to the technique or the procedure the researcher would adopt in
selecting items for the sample.
Sample design may as well lay down the number of items to be included
in the sample i.e., the size of the sample.

Sample design is determined before data are collected.
There are many sample designs from which a researcher can choose.
Some designs are relatively more precise and easier to apply than others.
Researcher must select/prepare a sample design which should be reliable
and appropriate for his research study.

Objective: The first step of sampling design is to define the objectives of
survey in clear and concrete terms. The sponsors or the researchers of the
survey should confirm that the objectives are commensurate with the money,
manpower and time limit available for the Survey.
Population: In order to meet the objectives of the survey, what should be the
population? This question should be answered in the second step. The
population should be clearly defined.

Sampling units and Frame
A decision has to be taken concerning a sampling unit before selecting sample.
Sampling unit may be a geographical one such as state, district, village, etc., or a
construction unit such as house, flat, etc., or it may be a social unit such as family,
club, school, etc., or it may be an individual. The researcher will have to decide one
or more of such units that he has to select for his study. The list of sampling units is
called as 'frame or sampling frame. Sampling frame contains the names of all items
of a universe (in case of finite universe only).

Size of sample
This refers to the number of items to be selected from the universe to constitute a
sample.
This is a major problem before a researcher. The size of sample should
neither be excessively large, nor too small. It should be optimum. An optimum
sample is one which full fills the requirements of efficiency, representativeness,
reliability and flexibility.

Parameters of interest: Statistical constants of the population are called as
parameters,
e.g., population mean, population proportion etc.
When we do census survey we get the actual value of parameters.
On the other hand, when we do sample survey we get the estimates of unknown
population parameters in place of their actual values.
Data collection: No irrelevant information should be collected and no essential
information should be discarded.
The objectives of the survey should be very much clear in the mind of surveyor.

Non-respondents: Because of practical difficulties, data may not be
collected for all the sampled units.
This non-response tends to change the results.
The reasons for non-response should be recorded by the investigator.
Selection of proper sampling design: he must select that design which,
for a given sample size and for a given cost, has a smaller sampling
error.

Organizing field work: The success of a survey depends on the reliable
field work. There should be efficient supervisory staff and trained
personals for the field work.
Pilot survey: It is always helpful to try out the research design on a
small scale before going to the field. This is called as 'pilot survey' or
‘pre-test'. It might give the better idea of practical problems and troubles.

Budgetary constraint: Cost considerations, from practical point of view,
have a major impact upon decisions relating to not only the size of the
sample but also to the type of sample.
This fact can even lead to the use of a non-probability sample.
SAMPLING AND NON-SAMPLING ERRORS
The errors involved in the collection of data are classified into sampling and non-
sampling errors.

Sampling Errors
Sampling errors arise due to the fact that only a part of the population has
been used to estimate population parameters and to draw inferences about
the population. Sampling errors are absent in a census survey.
Sampling error can be measured for a given sample design and size.
The measurement of sampling error is usually called the 'precision of the
sampling plan’. If we increase the samples size, the precision can be
improved.

Non-sampling Errors
Non-sampling errors arise at the stage of collection and preparation of
data and both thus are present in the sample survey as well as the census
survey. Thus the data obtained in census survey is free from sampling
errors, however subjected to non-sampling errors.
Non-sampling errors can be reduced by defining the sampling units,
frame and the population correctly and by employing efficient people in
the investigations.

Non-sampling errors arise due to a number of factors such as
inefficiency of field workers, non-response, bias due to interviewers,
etc. These errors are likely to grow when the number of units inspected
increases.
TYPES OF SAMPLING DESIGNS
‘non-probability sampling’ and 'probability sampling,'.

Non-probability Sampling
Non-probability sampling is that sampling procedure which does not
afford any basis for estimating the probability that each item in the
population has of being included in the sample.
Also known as...deliberate sampling, purposive sampling and judgement
sampling.
In this type of sampling, items for the sample are selected deliberately
by the researcher; his choice concerning the items remain supreme.

CONVENIENCE SAMPLING
Convenience sampling is a process of selecting subjects or units for
examination and analysis that is based on accessibility, ease, speed, and low
cost. Units are not purposefully or strategically selected.
It attempts to obtain a sample of convenient elements. Often, respondents are selected
because they happen to be in the right place at right time.
use of students, and members of social organizations.
mall intercept interviews without t qualifying the respondent.
depart n1ent stores using charge account lists.
"people on the street" interviews.

In such a design, personal element has a great chance of entering into
the selection of the sample. The investigator may select a sample which
shall yield results favourable to his point of view.
In small inquiries and research by individuals, this design may be
adopted because of the relative advantage of time and money inherent in
this method of sampling.

The samples so selected certainly do not possess the characteristic of
random samples. Quota sampling is also an example of non probability
sampling.
This type of sampling is very convenient and is relatively inexpensive.

Snow ball sampling
In snow ball sampling, an initial group of respondent is selected, usually
at random.
After being interviewed, these respondent are asked to identify others
who belong to the target population of interest.
Subsequent participants are selected based on the referrals.

Purposive (Judgmental) sampling
Purposive sampling, also known as judgmental, selective or subjective
sampling, reflects a group of sampling techniques that rely on the
judgment of the researcher; when it comes to selecting the units that are
to be studied. For examples …Specific People, Specific
cases/organizations, Specific events, Specific pieces of data.

Quota sampling
In this method, the population is divided into different groups or classes
according to different characteristics of the population and some
percentage of different groups in same population is fixed.

Probability Sampling
Probability sampling is also known as 'random sampling' or 'chance
sampling.
Under this sampling design, every item of the universe has an equal
chance of inclusion in the sample.
we can measure the errors of estimation or the significance of results
obtained from a random sample, and this fact brings out the superiority
of random sampling design over the deliberate sampling design.

Random sampling ensures the law of Statistical Regularity which states
that if on an average the sample chosen is a random one, the sample will
have the same composition and characteristics as the universe. Random
sampling is considered as the best technique of selecting a
representative sample.

Simple Random Sampling
Simple random sampling from a finite population refers to that method of sample
selection which gives each possible sample combination an equal probability of
being picked up and each item in the entire population to have an equal chance of
being included in the sample.
This applies to sampling without replacement. This relatively easy method of
obtaining a random sample can be simplified in actual practice by the use of random
number tables.

Complex Random Sampling Designs
Some complex random sampling designs, which are the mixture of probability and non-
probability sampling methods.
Systematic Sampling
The most practical way of sampling is to select every nth item on a list. Sampling of this type
is known as systematic sampling. An element of randomness is introduced into this kind of
sampling by using random numbers to pick up the unit with which to start. For instance, if a 4
percent sample is desired, the first item would be selected randomly from the first twenty-five
and thereafter every 25th item would automatically be included in the sample.

Thus, in systematic sampling only the first unit is selected randomly and the
remaining units of the sample are selected at fixed intervals.
It random can be taken as an improvement over a simple sample in as much as the
systematic sample is spread more evenly over the entire population.
If there is a hidden periodicity in the population, systematic sampling will prove to
be an inefficient method of sampling.
In practice, systematic sampling is used when lists of population are available and
they are of considerable length.

Stratified Sampling
Under stratified sampling the population is divided into several sub-populations that
are individually more homogeneous than the total population (the different sub-
populations are called 'strata') and then we select items from each stratum to
constitute a sample. Since each stratum is more homogeneous than the total
population, we are able to get more precise estimates for each stratum and by
estimating more accurately each of the component parts, we get a better estimate of
the whole. In brief, stratified sampling results in more reliable and detailed
information.

For example, a system-wide survey designed to determine the attitude
of students towards a new teaching plan, a state college system with 20
colleges might stratify the students with respect to class, section and
college. Stratification of this type is known as cross-stratification, and
up to a point such stratification increases the reliability of estimates and
is much used in opinion surveys.

From what has been stated above in respect of stratified sampling, we
can say that the sample so constituted is the result of successive
application of purposive (involved in stratification of items) and random
sampling methods. As such it is an example of mixed sampling. The
procedure wherein we first have stratification and then simple random
sampling is known as stratified random sampling.

Cluster Sampling
If the total area of interest happens to be a big one, a convenient way in which a
sample can be take is to divide the area into a number of smaller non-overlapping
areas and then to randomly select number of these smaller areas (usually called
clusters), with the ultimate sample consisting of all or samples of) units in these
small areas or clusters.
In cluster sampling the total population is divided into a number of relatively small
sub divisions which are themselves clusters of still smaller units and then some of
these clusters are randomly selected for inclusion in the overall sample.

Cluster sampling reduces cost by concentrating surveys in selected
clusters. But certainly it is less precise than random sampling. There is
also not as much information in n' observations within a cluster as there
happens to be in 'n' randomly drawn observations. Cluster sampling is
used only because of the economic advantage it possesses; estimates based
on cluster samples are usually more reliable per unit cost.
cluster designs, where the primary sampling unit represents a cluster of
units based on geographic area, are distinguished as area sampling.

Multi-stage Sampling
Multistage sampling is defined as a sampling method that divides the
population into groups (or clusters) for conducting research. It is a
complex form of cluster sampling, sometimes, also known as multi-
stage cluster sampling.
During this sampling method, significant clusters of the selected people
are split into sub-groups at various stages to make it simpler for primary
data collection.

There are four multistage steps to conduct multistage sampling
Step one: Choose a sampling frame, Considering the population of interest.
The researcher allocates a number to every group and selects a small sample
of population.
Step two: Select a sampling frame of relevant separate sub-groups. Do this
from related, different discrete groups selected in the previous stage.
Step three: Repeat the second step if necessary.
Step four: Using some variation of probability sampling, choose the
members of the sample group from the sub-groups.

Applications of multistage sampling
Applied to a multistage design where the population is too vast and researching every individual is
impossible.
To gather student perceptions from students belonging to various colleges, studying different courses
and located throughout the country.
To survey employees of a multinational company belonging to multiple locations in multiple
countries
Government bureaus use this method all the time to draw inferences from the population.
Multiphase sampling reduces the time taken to research an area. It also keeps a tab on the cost of the
research. The information collected from the samples is used to draw inferences from the population as
a whole.

Advantages of multistage sampling
It allows researchers to apply cluster or random sampling after determining the
groups.
Researchers can apply multistage sampling to make clusters and sub-clusters until the
researcher reaches the desired size or type of group.
Researchers can divide the population into groups without restrictions. It allows
flexibility to the researchers to choose the sample carefully.
It is useful while collecting primary data from a geographically dispersed population.

Cost-effective and time-effective because this method helps cut down the
population into smaller groups.
Finding the right survey sample becomes very convenient for researchers.
The researcher mindfully chooses the audience. It decreases the issues faced
during random sampling.
It does not need a complete list of all the members of the target
population,dramatically reducing sample preparation cost.

Types of multi-stage sampling
There are two types of multistage sampling -
Multi-stage cluster sampling and multi-stage random sampling.
 In market research,multistage sampling is the choosing of samples at
stages and choosing smaller sampling units at every step.

Multi-stage cluster sampling
Multistage cluster sampling is a complex type of cluster sampling. The
researcher divides the population into groups at various stages for better data
collection, management, and interpretation. These groups are called clusters.
For example, a researcher wants to know the different eating habits in
western Europe. It is practically impossible to collect data from every
household. The researcher will first choose the countries of interest. From
these countries, he/she chooses the regions or states to….

survey And from these regions, he/she further narrows down
his research by choosing specific cities and towns that
represent the region. The researcher does not interview all the
residents of the city or town. He/she further chooses particular
respondents from the selected cities to participate in research.
Here we see that clusters are selected at various stages until the
researcher narrows down to the sample required.

Multi-stage random sampling
In this case, the researcher chooses the samples randomly at each stage.
Here, the researcher does not create clusters, but he/she narrows down the
sample by applying random sampling. For example, a researcher wants to
understand pet feeding habits among people living in the USA. For this,
he/she requires a sample size of 200 respondents. The researcher selects
10 states out of 50 at random. Further, he/she randomly picks out 5
districts per state. From these 50 randomly selected states, he/she then
chooses 4 pet-owning households to conduct his research.

Tips for efficient multi-stage sampling
Think cautiously- Its good practice to brainstorm about a way to implement the
multistage approach.
Keep in mind that as there's no exact definition of multiphase sampling, there is no
conventional method on a route to mix the sampling methods (such as cluster, stratified,
and simple random).
The process design must be in a way that is both cost-effective and time-effective.
Retaining its randomness and its sample size is a must.
Consult an experienced and skilled expert when you apply this method for the first time.

Sequential Sampling
In this case the decision rests on the basis of more than two samples but
the number of samples is certain and decided in advance, the sampling
is known as multiple sampling. But when the number of samples is
more than two but it is neither certain nor decided in advance, this type
of system is often referred to as sequential sampling, Thus, in brief, we
can say that in sequential sampling, one can go on taking samples one
after another as long as one desires to do so.

Sampling design. types, methods, merits and demerits

More Related Content

Similar to Sampling design. types, methods, merits and demerits (20)

Recently uploaded (20)

Sampling design. types, methods, merits and demerits