Difference between revisions of "Statistics"

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= Introduction =
+
= Scope of this document =
 
   
 
   
 
The following is a background literature for
 
The following is a background literature for
Line 10: Line 10:
  
 
   
 
   
The teacher will get an overall idea of all the
+
= Syllabus =
sub topics required for school level statistics. The flow of how to
+
                       
build/develop an understanding of the topic for students from basics
+
{| border="1"
to more advanced aspects. Each subtopic will be developed by way of
+
|-
introductions, objectives, activities, evaluation and advanced and
+
|
additional information and resources.
+
'''Class '''
  
 
   
 
   
== Statistics ==
+
|
 +
'''Topic'''
 +
 
 
   
 
   
In early times, the meaning of statistics was
+
|-
restricted to information about states ( any political organization
+
|
with a government that has supreme independent authority over a
+
6
geographic area). This was later extended to include all collections
 
of information of all types, and later still it was extended to
 
include the analysis and interpretation of such data. In modern
 
terms, "statistics" means both sets of collected
 
information and analytical work which requires statistical inference.
 
  
 
   
 
   
Doing statistical analysis it is possible to test
+
|
numerical data for relevance, reliability and validity. In order to
+
'''Data handling '''
do this, statisticians must present data in such a form that others
 
can utilise the relevant information to enable them to make
 
judgements. One view is that the study of statistics is reported to
 
have started with the Englishman, John Graunt (1620 – 1674), who
 
collected and studied the death records in various cities of Britain.
 
He was fascinated by the patterns he found in the whole population.
 
Much of current day statistical analysis is of quite recent
 
development, the availability of cheap computing power acting as a
 
catalyst for the development of appropriate ways of presenting and
 
analysing data. In fact, the more advanced statistical analyses and
 
tests are based on probability theory, developed over the past few
 
centuries, but put into a more modern context by mathematical
 
statisticians such as Karl Pearson (1857 – 1936) , Sir Ronald
 
Fisher (1890 – 1962) , Jerzy Neyman (1894 – 1981).
 
  
 
   
 
   
The curricular objectives for school level
+
(i) What is data - choosing data to examine a hypothesis?
statistical work can be described as follows:
 
  
 
   
 
   
* To understand the meaning of data. The need for statistics and how to collect, organise and represent data in different ways.
+
(ii) Collection and organisation of data examples of organising
* Skills to represent and analyse data in tabular and graphical forms.
+
it in tally bars and a table.
* Understanding central tendency and computation of the measure of central tendency namely arithmetic mean, median and mode for both grouped and non-grouped data. Have the ability to use the appropriate central tendency to represent the data appropriately.
+
 
* Understanding dispersion determine the measures of dispersion such as range quartile deviation, mean deviation and standard deviation.
 
* Understand the limitations and drawbacks of statistics
 
 
   
 
   
=== Descriptive and Inferential Statistics ===
+
(iii) Pictograph- Need for scaling in pictographs
 +
interpretation & construction.
 +
 
 
   
 
   
 +
|-
 +
|
 +
7
  
 +
 +
|
 +
'''Data handling'''
  
 +
 +
(i) Collection and organisation of data – choosing the data
 +
to collect for a hypothesis testing.
  
 
   
 
   
When analysing data, for example, the marks
+
(ii) Mean, median and mode of ungrouped data understanding
achieved by 100 students for a piece of coursework, it is possible to
+
what they represent.
use both descriptive and inferential statistics in your analysis of
 
their marks. Typically, in most research conducted on groups of
 
people, you will use both descriptive and inferential statistics to
 
analyse your results and draw conclusions. So what are descriptive
 
and inferential statistics? And what are their differences?
 
  
 
   
 
   
==== Descriptive Statistics ====
+
(iii) Constructing bar graphs
 +
 
 
   
 
   
Descriptive statistics is the term given to the
+
(iv) Feel of probability using data through experiments.
analysis of data that helps describe, show or summarize data in a
+
Notion of chance in events like tossing coins, dice etc.
meaningful way such that, for example, patterns might emerge from the
+
Tabulating and counting occurrences of 1 through 6 in a number of
data. Descriptive statistics do not, however, allow us to make
+
throws. Preparing the bar graph. Comparing the observation with
conclusions beyond the data we have analysed or reach conclusions
+
that for a coin. Observing strings of throws, notion of
regarding any hypotheses we might have made. They are simply a way to
+
Randomness of ungrouped data.
describe our data.
 
  
 
   
 
   
Descriptive statistics are very important, as if
+
|-
we simply presented our raw data it would be hard to visualize what
+
|
the data was showing, especially if there was a lot of it.
+
9
Descriptive statistics therefore allow us to present the data in a
+
 
more meaningful way which allows simpler interpretation of the data.
+
For example, if we had the results of 100 pieces of students'
+
|
coursework, we may be interested in the overall performance of those
+
'''Statistics'''
students. We would also be interested in the distribution or spread
 
of the marks. Descriptive statistics allow us to do this. How to
 
properly describe data through statistics and graphs is an important
 
topic and discussed in other Laerd Statistics Guides. Typically,
 
there are two general types of statistic that are used to describe
 
data:
 
  
 
   
 
   
'''Measures of central tendency: '''these are
+
Mean, median, mode of grouped and
ways of describing the central position of a frequency distribution
+
un-grouped data, a review; range quartile deviation and mean
for a group of data. In this case, the frequency distribution is
+
diviation for a given grouped and un-grouped data; graphical
simply the distribution and pattern of marks scored by the 100
+
representation;construction and interpretation of histograms of
students from the lowest to the highest. We can describe this central
+
varying width, ogives and frequency polygons; review of random
position using a number of statistics, including the mode, median,
+
experiments leading to the concept of chance or probability.
and mean. You can read about measures of central tendency here.
 
  
 
   
 
   
'''Measures of spread:''' these are ways of
+
|-
summarizing a group of data by describing how spread out the scores
+
|
are. For example, the mean score of our 100 students may be 65 out of
+
10
100. However, not all students will have scored 65 marks. Rather,
 
their scores will be spread out. Some will be lower and others
 
higher. Measures of spread help us to summarize how spread out these
 
scores are. To describe this spread, a number of statistics are
 
available to us, including the range, quartiles, absolute deviation,
 
variance and standard deviation.
 
  
 
   
 
   
When we use descriptive statistics it is useful to
+
|
summarize our group of data using a combination of tabulated
+
'''Statistics'''
description (i.e. tables), graphical description (i.e. graphs and
 
charts) and statistical commentary (i.e. a discussion of the
 
results).
 
  
 
   
 
   
==== Inferential Statistics ====
+
Standard deviation of grouped and
 +
un-grouped data; calculation of standard deviation by direct
 +
method; coefficient of variation; construction and interpretation
 +
of pie charts
 +
 
 
   
 
   
We have seen that descriptive statistics provide
+
|}
information about our immediate group of data. For example, we could
+
 
calculate the mean and standard deviation of the exam marks for the
 
100 students and this could provide valuable information about this
 
group of 100 students. Any group of data like this, that includes all
 
the data you are interested, in is called a population. A population
 
can be small or large, as long as it includes all the data you are
 
interested in. For example, if you were only interested in the exam
 
marks of 100 students, then the 100 students would represent your
 
population. Descriptive statistics are applied to populations and the
 
properties of populations, like the mean or standard deviation, are
 
called parameters as they represent the whole population (i.e.
 
everybody you are interested in).
 
  
 
Often, however, you do not have access to the
 
whole population you are interested in investigating but only have a
 
limited number of data instead. For example, you might be interested
 
in the exam marks of all students in the UK. It is not feasible to
 
measure all exam marks of all students in the whole of the UK so you
 
have to measure a smaller sample of students, for example, 100
 
students, that are used to represent the larger population of all UK
 
students. Properties of samples, such as the mean or standard
 
deviation, are not called parameters but statistics. Inferential
 
statistics are techniques that allow us to use these samples to make
 
generalizations about the populations from which the samples were
 
drawn. It is, therefore, important the sample accurately represents
 
the population. The process of achieving this is called sampling.
 
Inferential statistics arise out of the fact that sampling naturally
 
incurs sampling error and thus a sample is not expected to perfectly
 
represent the population. The methods of inferential statistics are
 
(1) the estimation of parameter(s) and (2) testing of statistical
 
hypotheses.
 
  
 
= Mind Map =
 
 
   
 
   
  
  
 
[[File:KOER-%20Mathematics%20-%20Statistics_html_m14464871.jpg]]
 
  
 
   
 
   
= Data Handling =
+
= Curricular Objectives =
 
   
 
   
== Introduction ==
+
# To understand the meaning of data. The need for statistics and how to collect, organise and represent data in different ways.
 +
# Skills to represent and analyse data in tabular and graphical forms.
 +
# Understanding central tendency and computation of the measure of central tendency namely arthmetic mean, median and mode for both grouped and ungrouped data. Have the ability to use the appropriate central tendency depending on the data.
 +
# Understanding dispersion determine the measures of dispersion such as range quartile deviation, mean deviation and standard deviation.
 +
# Understand the limitations and drawbacks of statistics
 
   
 
   
Data is a
+
= Concept Map =
collection of facts, such as values or measurements. It can be
 
numbers, words, measurements, observations or even just descriptions
 
of things. Statistical work is done for problem solving. For problem
 
solving, we first have to understand the problem (postulating
 
hypotheses ) , then we have to collect relevant data , after which we
 
must be able to present the data, finally analyse the data and make
 
conclusions related to the original hypotheses. Statistics provides
 
us with tools to analyse data and draw conclusions from a large set
 
of data by organising the data in the set in different ways and
 
analysing the data by observing patterns. Data handling would
 
include identifying data, collecting data, organising/representing
 
data and summarising data.
 
 
   
 
   
== Objective ==
+
[[Image:Statistics_html_m14464871.jpg]]
 +
 
 +
 
 
   
 
   
* What is statistical work and why and where we would need to use this.
+
 
* To understand different types of data: qualitative and quantitative
+
 
* To understand the sources of data : Primary and Secondary
 
* To learn how to collect, classify and display data; data is information that is used in any process connected with statistics.
 
 
   
 
   
== Data ==
+
= Theme Plan =
+
                                                     
The term data refers to qualitative or
+
{| border="1"
quantitative attributes of a variable or set of variables.Data refers
+
|-
to the pieces of information that have been observed and recorded,
+
|
from an experiment or a survey. There are two types of data: primary
+
 
and secondary. The word ”data” is the plural of the word ”datum”,
+
 
and therefore one should say, ”the data are” and not ”the data
+
is”. Data can be classified as primary or secondary, and primary or
+
|
secondary data can be classified as qualitative or quantitative.
+
THEME PLAN FOR THE TOPIC
 +
STATISTICS
  
 
   
 
   
The figure below summarises the classifications of
+
|
data. Primary data describes the original data that have been
 
collected. This type of data is also known as raw data. Often the
 
primary data set is very large and is therefore summarised or
 
processed to extract meaningful information. Qualitative data is
 
information that cannot be written as numbers, for example, if you
 
were collecting data from people on how they feel or what their
 
favourite colour is.Quantitative data is information that can be
 
written as numbers, for example, if you were collecting data from
 
people on their height or weight.
 
  
Secondary data is
 
primary data that has been summarised or processed, for example, the
 
set of colours that people gave as favourite colours would be secondary data because it is a
 
summary of responses.
 
Data already collected prior our use is secondary data. Primary data
 
is what we collect as a part of our study. All processed data
 
therefore is also secondary.
 
  
Transforming primary
 
data into secondary data through analysis, grouping or organisation
 
into secondary data is the process of generating information.
 
 
   
 
   
=== Purpose of Collecting Primary Data ===
+
|
 
Data is collected to
 
provide answers that help with understanding a particular situation.
 
Here are examples to illustrate some real world data collections
 
scenarios in the categories of qualitative and quantitative data.
 
  
  
=== Qualitative Data ===
 
 
   
 
   
* The local government might want to know how many residents have electricity and might ask the question: ”Does your home have a safe supply of electricity?”
+
|-
* A supermarket manager might ask the question: “What flavours of soft drink should be stocked in my supermarket?” The question asked of customers might be “What is your favourite soft drink?” Based on the customers’ responses, the manager can make an informed decision as to what soft drinks to stock.
+
|
* A company manufacturing medicines might ask “How effective is our pill at relieving a headache?” The question asked of people using the pill for a headache might be: “Does taking the pill relieve your headache?” Based on responses, the company learns how effective their product is.
+
'''CLASS'''
* A motor car company might want to improve their customer service, and might ask their customers: “How can we improve our customer service?”
+
 
* A teacher may ask “How many hours of TV by students on TV' to get an idea of what children are learning from TV at home and how it supplements (or affects) the learning in the school
 
 
=== Quantitative Data ===
 
 
   
 
   
* A cell phone manufacturing company might collect data about how often people buy new cell phones and what factors affect their choice, so that the cell phone company can focus on those features that would make their product more attractive to buyers.
+
|
* A town councillor might want to know how many accidents have occurred at a particular intersection, to decide whether a robot should be installed. The councillor would visit the local police station to research their records to collect the appropriate data.
+
'''SUBTOPIC'''
* A supermarket manager might ask the question: “What flavours of soft drink should be stocked in my supermarket?” The question asked of customers might be “What is your favourite soft drink?” Based on the customers’ responses, the manager can make an informed decision as to what soft drinks to stock.
+
 
* What kind of TV programs are watched by students, how many are educational in nature.
 
 
   
 
   
However, it is important to note that
+
|
different questions reveal different features of a situation, and
+
'''CONCEPT
that this affects the ability to understand the situation. For
+
DEVELOPMENT'''
example, if the question in the list What kind of TV programs are
 
watched by students, how many are educational in nature. was
 
re-phrased to be: Do your children watch educational programs on TV
 
and if you answered yes, but most programs being watched were of
 
entertainment value, , then this could give the wrong impression that
 
TV was being used as an educational tool in your home .
 
  
== Data Collection ==
 
 
   
 
   
The method of
+
|
collecting the data must be appropriate to the question being asked.
+
'''KNOWLEDGE'''
Some examples of data collecting methods are:
+
 
 
 
# Experiments
 
# Questionnaires, surveys, focus group discussions and interviews
 
# Other sources (friends, family, newspapers, books, magazines and now increasingly the Internet)
 
# Observation
 
# Specialised equipment (rainwater gauges to measure rainfall in a place, various medical equipment that collect information about different biological processes)
 
 
   
 
   
The most important
+
|
aspect of each method of data collecting is to clearly formulate the
+
'''SKILL'''
question that is to be answered. The details of the data collection
 
should therefore be structured to take your question into account.
 
  
You must have observed your teacher recording the attendance of students in your class
 
everyday, or recording marks obtained by you after every test or
 
examination. Similarly, you must have also seen a cricket score
 
board. One score boards have been illustrated here :
 
 
   
 
   
NatWest One Day
+
|
International Series: England v India
+
'''ACTIVITY'''
Friday, 16 September 2011 at
 
The Swalec Stadium
 
  
 
   
 
   
'''England beat India
 
by 6 wickets (D/L). '''England won the toss and decided to field
 
     
 
{| border="1"
 
 
|-
 
|-
 
|  
 
|  
[[India Innings]]
+
6
  
 
   
 
   
304 for 6 (50.0 overs)
+
|
 +
Data reading, comprehension and data
 +
collection
  
 
   
 
   
|-
 
 
|  
 
|  
[[England Innings]]
+
Data is a
 +
collection of facts, such as values or measurements. It can be
 +
numbers, words, measurements, observations or even just
 +
descriptions of things.
  
 
   
 
   
241 for 4 (32.2 overs)
+
 
  
 
   
 
   
|}
+
The need for statistics – to be
 
+
able to analyse and draw conclusions for a large set of data by
 +
organising data in different ways and observing patterns.
  
 
   
 
   
'''India
 
1st Innings - Close'''
 
 
                                                                                                     
 
{| border="1"
 
|-
 
 
|  
 
|  
 
+
Data and patterns of data. Raw
 +
Scores Class Intervals, Tally Marks and usage. Frequency in
 +
statistcs.
  
 
   
 
   
 
|  
 
|  
 
+
Identification of patterns and
 +
different methods of collection of data and collation of data
  
 
   
 
   
 
|  
 
|  
Runs
+
ACTIVITY1
  
 
   
 
   
 +
|-
 
|  
 
|  
Balls
+
7
  
 
   
 
   
 
|  
 
|  
4s
+
Graphical representation of Data
  
 
   
 
   
 
|  
 
|  
6s
+
Tabular
 +
data can be also represented in the form of a picture ( charts)
 +
as visual representations can sometimes be easier to interpret.
  
 
   
 
   
|-
+
 
|
 
P Patel
 
  
 
   
 
   
|
+
There are
c Bresnan
+
different types of pictorial representations that can be used to
 +
represent different type of data.
  
 
   
 
   
|
+
 
b Swann
 
  
 
   
 
   
|
+
Looking at the data be able to
'''19'''
+
select the chart that would clearly represent the data as well as
 +
convey intended information about the data
  
 
   
 
   
 
|  
 
|  
39
+
Frequency Distribution, Class
 +
intervals, Bar Chart, Pie Chart , Histogram
  
 
   
 
   
 
|  
 
|  
0
+
Given statistical data in a table
 +
format, develop the skills to select the appropriate chart.
 +
Represent the data as a chart and be able to interpret data
 +
given a chart.
  
 
   
 
   
 
|  
 
|  
0
+
ACTIVITY 2
  
 
   
 
   
 
|-
 
|-
 
|  
 
|  
Rahane
+
9
  
 
   
 
   
 
|  
 
|  
c Finn
+
Central tendency
  
 
   
 
   
 
|  
 
|  
b Dernbach
+
A measure
 +
of central tendency is a single value that attempts to describe a
 +
set of data by identifying the central position within that set of
 +
data.
  
 
   
 
   
|
+
The mean, median and mode are all
'''26'''
+
valid measures of central tendency but, under different
 +
conditions, some measures of central tendency become more
 +
appropriate to use than others.
  
 
   
 
   
 
|  
 
|  
47
+
Mean, Median and Mode as methods of
 +
calculating central tendency
  
 
   
 
   
 
|  
 
|  
3
+
Calculation of mean and median
 +
Analyse data and make conclusions
  
 
   
 
   
 
|  
 
|  
0
+
ACTIVITY 3
  
 
   
 
   
 
|-
 
|-
 
|  
 
|  
Dravid
+
9 & 10
  
 
   
 
   
 
|  
 
|  
 
+
Dispersion
  
 
   
 
   
 
|  
 
|  
b Swann
+
A measure
 +
of dispersion is a measure of spread, is used to describe the
 +
variability in a sample or population.
  
 
   
 
   
|
+
 
'''69'''
 
  
 
   
 
   
|
+
It is
79
+
usually used in conjunction with a measure of central tendency,
 +
such as, the mean or median, to provide an overall description of
 +
a set of data.
  
 
   
 
   
|
+
 
4
 
  
 
   
 
   
|
+
It important to measure the spread
0
+
of data because we can understand its relationship with measures
 +
of central tendency to make more accurate interpretation of data.
  
 
   
 
   
|-
 
 
|  
 
|  
Kohli
+
Range, Quartile, Standard Deviation
 +
, Cumulative Frequency
  
 
   
 
   
 
|  
 
|  
hit wicket
+
Calculation of Co-efficient of
 +
Variation. Meaning and interpretation of C.V. Analyse data and
 +
make conclusions
  
 
   
 
   
 
|  
 
|  
b Swann
+
 
  
 
   
 
   
|  
+
|}
'''107'''
+
 
  
 
   
 
   
|
 
93
 
  
 +
 +
 +
= Statistics =
 
   
 
   
|
+
'''Statistics'''
9
+
is the study of the collection, organization, and interpretation of
 +
data. It deals with all aspects of this, including the planning of
 +
data collection in terms of the design of surveys and experiments.
 +
(source [[http://en.wikipedia.org/wiki/Statistics]])
  
 
   
 
   
|
+
 
1
 
  
 
   
 
   
|-
+
''Statistics
|
+
is a set of tools used to organize and analyze data. Data must either
Raina
+
be numeric in origin or transformed by researchers into numbers. For
 +
instance, statistics could be used to analyze percentage scores
 +
English students receive on a grammar test: the percentage scores
 +
ranging from 0 to 100 are already in numeric form. Statistics could
 +
also be used to analyze grades on an essay by assigning numeric
 +
values to the letter grades, e.g., A=4, B=3, C=2, D=1, and F=0.
 +
Though this is not strictly necessary, statistical computations can
 +
be done on a set of textual data as in this case, translating them
 +
into numeric data has been a convention in the past.''
  
 
   
 
   
|
 
c Bresnan
 
  
+
 
|
 
b Finn
 
  
 
   
 
   
|
+
A statistician is someone who is
'''15'''
+
particularly well versed in the ways of thinking necessary for the
 +
successful application of statistical analysis. Such people have
 +
often gained this experience through working in any of a wide number
 +
of fields. There is also a discipline called ''mathematical
 +
statistics'', which is concerned with the theoretical basis of the
 +
subject.
  
 
   
 
   
|
+
The word ''statistics'', when
15
+
referring to the scientific discipline, is singular, as in
 +
"Statistics is an art."This should not be confused with the
 +
word ''statistic'', referring to a quantity (such as mean or
 +
median) calculated from a set of data,whose plural is ''statistics''
 +
("this statistic seems wrong" or "these statistics are
 +
misleading"). Source - http://en.wikipedia.org/wiki/Statistics
 +
 
 +
 
 +
Statistical is concerned with the planning of
 +
studies, especially with the design of randomized experiments and
 +
with the planning of surveys using random sampling.
  
 
   
 
   
|
+
Of course, the data from a randomized study can be
0
+
analyzed to consider secondary hypotheses or to suggest new ideas. A
 +
secondary analysis of the data from a planned study uses tools from
 +
data analysis.
  
 
   
 
   
|
+
Data analysis is divided into:
1
 
  
 
   
 
   
|-
+
* descriptive statistics - the part of statistics that describes data, i.e. summarises the data and their typical properties.
|
 
Dhoni
 
 
 
 
   
 
   
|
+
* inferential statistics - the part of statistics that draws conclusions from data (using some model for the data): For example, inferential statistics involves selecting a model for the data, checking whether the data fulfill the conditions of a particular model, and with quantifying the involved uncertainty (e.g. using confidence intervals).
not out
 
 
 
 
   
 
   
|
 
  
  
 
|
 
'''50'''
 
  
 
   
 
   
|
+
While the tools of data analysis work best on data
26
+
from randomized studies, they are also applied to other kinds of data
 +
--- for example, from natural experiments and observational studies,
 +
in which case the inference is dependent on the model chosen by the
 +
statistician, and so subjective.
  
 
   
 
   
|
+
Mathematical statistics has been inspired by and
5
+
has extended many procedures in applied statistics.
  
 
   
 
   
|
+
== Descriptive and Inferential Statistics ==
2
 
 
 
 
   
 
   
|-
 
|
 
Jadeja
 
  
 
|
 
c Bopara
 
  
 
|
 
b Dernbach
 
  
 
   
 
   
|
+
When analysing data, for example, the marks
'''0'''
+
achieved by 100 students for a piece of coursework, it is possible to
 +
use both descriptive and inferential statistics in your analysis of
 +
their marks. Typically, in most research conducted on groups of
 +
people, you will use both descriptive and inferential statistics to
 +
analyse your results and draw conclusions. So what are descriptive
 +
and inferential statistics? And what are their differences?
  
 
   
 
   
|
 
1
 
  
 
|
 
0
 
  
 
|
 
0
 
  
 
   
 
   
|-
+
=== Descriptive Statistics ===
|
 
Ashwin
 
 
 
 
   
 
   
|
 
not out
 
  
 
|
 
  
  
 
   
 
   
|
+
Descriptive statistics is the term given to the
'''0'''
+
analysis of data that helps describe, show or summarize data in a
 +
meaningful way such that, for example, patterns might emerge from the
 +
data. Descriptive statistics do not, however, allow us to make
 +
conclusions beyond the data we have analysed or reach conclusions
 +
regarding any hypotheses we might have made. They are simply a way to
 +
describe our data.
  
 
   
 
   
|
 
0
 
  
+
 
|
 
0
 
  
 
   
 
   
|
+
Descriptive statistics are very important, as if
0
+
we simply presented our raw data it would be hard to visulize what
 +
the data was showing, especially if there was a lot of it.
 +
Descriptive statistics therefore allow us to present the data in a
 +
more meaningful way which allows simpler interpretation of the data.
 +
For example, if we had the results of 100 pieces of students'
 +
coursework, we may be interested in the overall performance of those
 +
students. We would also be interested in the distribution or spread
 +
of the marks. Descriptive statistics allow us to do this. How to
 +
properly describe data through statistics and graphs is an important
 +
topic and discussed in other Laerd Statistics Guides. Typically,
 +
there are two general types of statistic that are used to describe
 +
data:
  
 
   
 
   
|-
 
|
 
'''Extras'''
 
  
 
|
 
  
  
 
   
 
   
|
+
'''Measures of central tendency: '''these are
6w 1b 11lb
+
ways of describing the central position of a frequency distribution
 +
for a group of data. In this case, the frequency distribution is
 +
simply the distribution and pattern of marks scored by the 100
 +
students from the lowest to the highest. We can describe this central
 +
position using a number of statistics, including the mode, median,
 +
and mean. You can read about measures of central tendency here.
  
 
   
 
   
|
 
'''18'''
 
  
 
|
 
  
  
 
   
 
   
|-
+
'''Measures of spread:''' these are ways of
|
+
summarizing a group of data by describing how spread out the scores
'''Total'''
+
are. For example, the mean score of our 100 students may be 65 out of
 +
100. However, not all students will have scored 65 marks. Rather,
 +
their scores will be spread out. Some will be lower and others
 +
higher. Measures of spread help us to summarize how spread out these
 +
scores are. To describe this spread, a number of statistics are
 +
available to us, including the range, quartiles, absolute deviation,
 +
variance and standard deviation.
  
 
   
 
   
|
 
  
  
 
|
 
for 6
 
  
 
   
 
   
|
+
When we use descriptive statistics it is useful to
'''304'''
+
summarize our group of data using a combination of tabulated
 +
description (i.e. tables), graphical description (i.e. graphs and
 +
charts) and statistical commentary (i.e. a discussion of the
 +
results).
  
 
   
 
   
|
 
'''(50.0 ovs)'''
 
  
 
|}
 
  
  
     
 
{| border="1"
 
|-
 
|                                                       
 
{| border="1"
 
|-
 
|
 
Bowler
 
 
 
   
 
   
|
+
== Inferential Statistics ==
Overs
+
  
 
|
 
Maidens
 
  
 
|
 
Runs
 
  
 
   
 
   
|
+
We have seen that descriptive statistics provide
Wickets
+
information about our immediate group of data. For example, we could
 +
calculate the mean and standard deviation of the exam marks for the
 +
100 students and this could provide valuable information about this
 +
group of 100 students. Any group of data like this, that includes all
 +
the data you are interested, in is called a population. A population
 +
can be small or large, as long as it includes all the data you are
 +
interested in. For example, if you were only interested in the exam
 +
marks of 100 students, then the 100 students would represent your
 +
population. Descriptive statistics are applied to populations and the
 +
properties of populations, like the mean or standard deviation, are
 +
called parameters as they represent the whole population (i.e.
 +
everybody you are interested in).
  
 
   
 
   
|-
 
|
 
Bresnan
 
  
+
 
|
 
9.0
 
  
 
   
 
   
|
+
Often, however, you do not have access to the
0
+
whole population you are interested in investigating but only have a
 +
limited number of data instead. For example, you might be interested
 +
in the exam marks of all students in the UK. It is not feasible to
 +
measure all exam marks of all students in the whole of the UK so you
 +
have to measure a smaller sample of students, for example, 100
 +
students, that are used to represent the larger population of all UK
 +
students. Properties of samples, such as the mean or standard
 +
deviation, are not called parameters but statistics. Inferential
 +
statistics are techniques that allow us to use these samples to make
 +
generalizations about the populations from which the samples were
 +
drawn. It is, therefore, important the sample accurately represents
 +
the population. The process of achieving this is called sampling
 +
(sampling strategies are discussed in detail here on our sister
 +
site). Inferential statistics arise out of the fact that sampling
 +
naturally incurs sampling error and thus a sample is not expected to
 +
perfectly represent the population. The methods of inferential
 +
statistics are (1) the estimation of parameter(s) and (2) testing of
 +
statistical hypotheses.
  
 
   
 
   
|
+
= Data handling =
62
 
 
 
 
   
 
   
|
+
The term data refers to qualitative or
0
+
quantitative attributes of a variable or set of variables.Data refers
 +
to the pieces of information that have been observed and recorded,
 +
from an experiment or a survey. There are two types of data: primary
 +
and secondary. The word ”data” is the plural of the word ”datum”,
 +
and therefore one should say, ”the data are” and not ”the data
 +
is”. Data can be classified as primary or secondary, and primary or
 +
secondary data can be classified as qualitative or quantitative.
  
 
   
 
   
|-
+
Figure 16.1 summarises the classifications of
|
+
data. Primary data describes the original data that have been
Finn
+
collected. This type of data is also known as raw data. Often the
 +
primary data set is very large and is therefore summarised or
 +
processed to extract meaningful information. Qualitative data is
 +
information that cannot be written as numbers, for example, if you
 +
were collecting data from people on how they feel or what their
 +
favourite colour is.Quantitative data is information that can be
 +
written as numbers, for example, if you were collecting data from
 +
people on their height or weight.
 +
 
 +
 
 +
 
  
 
   
 
   
|
+
 
10.0
 
  
 
   
 
   
|
+
 
1
 
  
 
   
 
   
|
+
 
44
 
  
 
   
 
   
|
+
 
1
 
  
 
   
 
   
|-
+
 
|
 
Dernbach
 
  
 
   
 
   
|
+
 
10.0
 
  
 
   
 
   
|
+
 
0
 
  
 
   
 
   
|
+
 
73
 
  
 
   
 
   
|
 
2
 
  
 
|-
 
|
 
Swann
 
  
 
   
 
   
|
 
9.0
 
  
 
|
 
0
 
  
 
   
 
   
|
+
Secondary data is
34
+
primary data that has been summarised or processed, for example, the
 +
set
  
 
   
 
   
|
+
of colours that people
3
+
gave as favourite colours would be secondary data because it is a
  
 
   
 
   
|-
+
summary of responses.
|
+
Data already collected prior our use is secondary data. Primary data
S Patel
+
is what we collect as a part of our study. All processed data
 +
therefore is also secondary.
  
 
   
 
   
|
 
8.0
 
  
 
|
 
0
 
  
 
   
 
   
|
+
Transforming primary
55
+
data into secondary data through analysis, grouping or organisation
 +
into secondary data is the process of generating information.
 +
 
 +
 +
 
 +
 
 +
 +
== Purpose of Collecting Primary Data ==
 +
 +
Data is collected to
 +
provide answers that help with understanding a particular situation.
 +
Here are examples to illustrate some real world data collections
 +
scenarios in the categories of qualitative and quantitative data.
  
 
   
 
   
|
+
== Qualitative Data ==
0
+
 +
• The local
 +
government might want to know how many residents have electricity and
 +
might
  
 
   
 
   
|-
+
ask the question: ”Does
|
+
your home have a safesupply of electricity?”
Bopara
 
  
 
   
 
   
|
+
• A supermarket
4.0
+
manager might ask the question: “What flavours of soft drink should
 +
be
  
 
   
 
   
|
+
stocked in my
0
+
supermarket?” The question asked of customers might be “What is
 +
your
  
 
   
 
   
|
+
favourite soft drink?”
24
+
Based on the customers’ responses, the manager can make an
  
 
   
 
   
|
+
informed decision as to
0
+
what soft drinks to stock.
  
 
   
 
   
|}
+
• A company
 +
manufacturing medicines might ask “How effective is our pill at
 +
relieving a
  
 +
 +
headache?” The
 +
question asked of people using the pill for a headache might be:
 +
“Does
  
 
   
 
   
|}
+
taking the pill relieve
 +
your headache?” Based on responses, the company learns how
 +
 
 
   
 
   
== Recording Data ==
+
effective their product
 +
is.
 +
 
 
   
 
   
Let us take an example of a class which is
+
• A motor car company
preparing to go for a picnic. The teacher asked the students to give
+
might want to improve their customer service, and might ask their
their choice of fruits out of banana, apple, orange or guava. Uma is
 
asked to prepare the list. She prepared a list of all the children
 
and wrote the choice of fruit against each name. This list would help
 
the teacher to distribute fruits according to the choice.
 
         
 
{| border="1"
 
|-
 
|
 
Raghav — Banana
 
  
 
   
 
   
Preeti — Apple
+
customers: “How can
 +
we improve our customer service?”
  
 
   
 
   
Amar — Guava
+
A teacher may ask “How
 +
many hours of TV by students on TV' to get an idea of what children
 +
are learning from TV at home and how it supplements (or affects) the
 +
learning in the school
  
 
   
 
   
Fatima — Orange
+
 
  
 
   
 
   
Amita — Apple
+
== Quantitative Data ==
 +
 +
• A cell phone manufacturing company might
 +
collect data about how often people buy new
  
 
   
 
   
Raman — Banana
+
cell phones and what factors affect their choice,
 +
so that the cell phone company can focus
  
 
   
 
   
Radha — Orange
+
on those features that would make their product
 +
more attractive to buyers.
  
 
   
 
   
Farida — Guava
+
• A town councillor might want to know how many
 +
accidents have occurred at a particular
  
 
   
 
   
Anuradha — Banana
+
intersection, to decide whether a robot should be
 +
installed. The councillor would visit the
  
 
   
 
   
Rati — Banana
+
local police station to research their records to
 +
collect the appropriate data.
  
 
   
 
   
|
+
• A supermarket manager might ask the question:
Bhawana — Apple
+
“What flavours of soft drink should be
  
 
   
 
   
Manoj — Banana
+
stocked in my supermarket?” The question asked
 +
of customers might be “What is your
  
 
   
 
   
Donald — Apple
+
favourite soft drink?” Based on the customers’
 +
responses, the manager can make an
  
 
   
 
   
Maria — Banana
+
informed decision as to what soft drinks to stock.
  
 
   
 
   
Uma — Orange
+
What kind of TV programs are watched by students,
 +
how many are educational in nature.
  
 
   
 
   
Akhtar — Guava
+
 
 +
 
  
 
   
 
   
Ritu — Apple
+
 
 +
 
  
 
   
 
   
Salma — Banana
+
However, it is important to note that different
 +
questions reveal different features of a situation, and that this
 +
affects the ability to understand the situation. For example, if the
 +
question in the list What kind of TV programs are watched by
 +
students, how many are educational in nature. was re-phrased to be:
 +
Do your children watch educational programs on TV and if you answered
 +
yes, but most programs being watched were of entertainment value, ,
 +
then this could give the wrong impression that TV was being used as
 +
an educational tool in your home .
  
 
   
 
   
Kavita — Guava
+
= Methods of Data Collection =
 
 
 
   
 
   
Javed — Banana
+
The method of
 +
collecting the data must be appropriate to the question being asked.
 +
Some
  
 
   
 
   
|}  
+
examples of data
 +
collecting methods are:
 +
 
 +
 
 +
# Experiments
 +
# Questionnaires, surveys, focus group discussions and interviews
 +
# Other sources (friends, family, newspapers, books, magazines and now increasingly the Internet)
 +
# Observation
 +
# Specialised equipment (rainwater guages to measure rainfall in a place, various medical equipment that collect information about different biological processes)
 +
   
  
Example 1 : A teacher
 
wants to know the choice of food of each student as part of the
 
mid-day meal programme. The teacher assigns the task of collecting
 
this information to Maria. Maria does so using a paper and a pencil.
 
After arranging the choices in a column, she puts against a choice of
 
food one ( | ) mark for every student making that choice.
 
           
 
{| border="1"
 
|-
 
|
 
Choice
 
  
 
   
 
   
|
+
The most important
Number of students
+
aspect of each method of data collecting is to clearly formulate the
 +
question that is to be answered. The details of the data collection
 +
should therefore be structured to take your question into account.
  
 
   
 
   
|-
+
 
|
 
Rice only
 
  
 
   
 
   
Chapati only
+
You must have observed
 +
your teacher recording the attendance of students in your class
 +
everyday, or recording marks obtained by you after every test or
 +
examination. Similarly, you must have also seen a cricket score
 +
board. One score boards have been illustrated here :
  
 
   
 
   
Both rice and chapati
 
  
 
|
 
|||||||||||||||||
 
  
 
   
 
   
|||||||||||||
 
  
 
||||||||||||||||||||
 
  
+
     
|}
 
 
Umesh, after seeing the
 
table suggested a better method to count the students. He asked
 
Maria to organise the marks ( | ) in a group of ten as shown below :
 
 
 
             
 
 
{| border="1"
 
{| border="1"
 
|-
 
|-
 
|  
 
|  
Choice
+
|}
 +
 
  
 
   
 
   
|
+
NatWest One Day
Tally marks
+
International Series: England v India
 +
Friday, 16 September 2011 at
 +
The Swalec Stadium
  
 
   
 
   
|
+
'''England beat India
Number of students
+
by 6 wickets (D/L). '''England won the toss and decided to field
  
+
       
 +
{| border="1"
 
|-
 
|-
 
|  
 
|  
Rice only
+
[[India Innings]]
  
 
   
 
   
Chapati only
+
304 for 6 (50.0 overs)
 
 
 
Both rice and chapati
 
  
 
   
 
   
 +
|-
 
|  
 
|  
|||||||||| |||||||
+
[[England Innings]]
  
 
   
 
   
|||||||||| |||
+
241 for 4 (32.2 overs)
  
 
   
 
   
|||||||||| ||||||||||
+
|}
  
 
|
 
17
 
  
 
   
 
   
13
+
'''India
 +
1st Innings - Close'''
 +
 
 +
                                                                                                     
 +
{| border="1"
 +
|-
 +
 +
 +
|
 +
Runs
  
 
   
 
   
20
+
|
 +
Balls
  
 
   
 
   
|
+
|  
 
+
4s
  
 
   
 
   
Rajan made it simpler
+
|
by asking her to make groups of five instead of ten, as
+
6s
  
 
   
 
   
shown below :
 
 
                 
 
{| border="1"
 
 
|-
 
|-
 
|  
 
|  
Choice
+
P Patel
  
 
   
 
   
 
|  
 
|  
Tally marks
+
c Bresnan
  
 
   
 
   
 
|  
 
|  
Number of students
+
b Swann
  
 
   
 
   
|-
 
 
|  
 
|  
Rice only
+
'''19'''
  
 
   
 
   
Chapati only
+
|
 +
39
  
 
   
 
   
Both rice and chapati
+
|
 +
0
  
 
   
 
   
 
|  
 
|  
||||| |||||
+
0
||||| ||
 
  
 
   
 
   
||||| |||||  
+
|-
|||
+
|  
 +
Rahane
  
 
   
 
   
||||| ||||| ||||| |||||
+
|  
 +
c Finn
  
 
   
 
   
 
|  
 
|  
17
+
b Dernbach
  
 
   
 
   
13
+
|
 +
'''26'''
  
 
   
 
   
20
+
|
 +
47
  
 
   
 
   
|
+
|  
 +
3
  
=== Meaning of Frequency ===
 
 
   
 
   
Frequency means the number of occurrences within a
 
given time period. It is not easy to answer the
 
question looking at the choices written haphazardly. We arrange the
 
data in Table below using tally marks.
 
                         
 
{| border="1"
 
|-
 
 
|  
 
|  
Subject
+
0
  
 
   
 
   
 +
|-
 
|  
 
|  
Tally Marks
+
Dravid
  
 
   
 
   
 +
 
|  
 
|  
Number of Students
+
b Swann
  
 
   
 
   
|-
 
 
|  
 
|  
Art
+
'''69'''
  
 
   
 
   
 
|  
 
|  
|||| ||
+
79
  
 
   
 
   
 
|  
 
|  
7
+
4
 +
 
 +
 +
|
 +
0
  
 
   
 
   
 
|-
 
|-
 
|  
 
|  
Mathematics
+
Kohli
 +
 
 +
 +
|
 +
hit wicket
  
 
   
 
   
 
|  
 
|  
||||
+
b Swann
  
 
   
 
   
 
|  
 
|  
5
+
'''107'''
  
 
   
 
   
|-
 
 
|  
 
|  
Science
+
93
  
 
   
 
   
 
|  
 
|  
|||||
+
9
  
 
   
 
   
 
|  
 
|  
6
+
1
  
 
   
 
   
 
|-
 
|-
 
|  
 
|  
English
+
Raina
  
 
   
 
   
 
|  
 
|  
||||
+
c Bresnan
  
 
   
 
   
 
|  
 
|  
4
+
b Finn
  
 
   
 
   
|}
+
|  
 +
'''15'''
  
The number of tallies
 
before each subject gives the number of students who like that
 
particular subject. This is known as the frequency of that subject.
 
Frequency gives the number of times that a particular entry occurs.
 
From above table, Frequency of students who like English is 4
 
Frequency of students who like Mathematics is 5 The table made is
 
known as frequency distribution table as it gives the number of times
 
an entry occurs.
 
 
   
 
   
=== Categorical Frequency Distributions ===
+
|
 +
15
 +
 
 
   
 
   
Categorical frequency
+
|
distributions - can be used for data that can be placed in specific
+
0
categories, such as nominal- or ordinal-level data. (nominal or
+
 
ordinal also called discrete data is where we can distinctly count
+
the occurrences of a variable).
+
|
 +
1
 +
 
 
   
 
   
Examples - political
 
affiliation, religious affiliation, blood type etc. Below is Blood
 
Type frequency distribution example.
 
                             
 
{| border="1"
 
 
|-
 
|-
 
|  
 
|  
Class
+
Dhoni
  
 
   
 
   
 
|  
 
|  
Frequency
+
not out
  
 
   
 
   
 +
 
|  
 
|  
Percent
+
'''50'''
  
 
   
 
   
|-
 
 
|  
 
|  
A
+
26
  
 
   
 
   
Line 1,126: Line 1,062:
 
   
 
   
 
|  
 
|  
20
+
2
  
 
   
 
   
 
|-
 
|-
 
|  
 
|  
B
+
Jadeja
  
 
   
 
   
 
|  
 
|  
7
+
c Bopara
  
 
   
 
   
 
|  
 
|  
28
+
b Dernbach
  
 
   
 
   
|-
 
 
|  
 
|  
C
+
'''0'''
  
 
   
 
   
 
|  
 
|  
9
+
1
  
 
   
 
   
 
|  
 
|  
36
+
0
  
 
   
 
   
|-
 
 
|  
 
|  
D
+
0
  
 
   
 
   
 +
|-
 
|  
 
|  
4
+
Ashwin
  
 
   
 
   
 
|  
 
|  
16
+
not out
  
 
   
 
   
|}
+
|   
   
+
|
== Activities ==
+
'''0'''
 
=== Activity 1 Data Collection ===
 
 
==== Learning Objectives ====
 
 
Understand collection of data .
 
  
 
   
 
   
==== Materials and resources required ====
+
|
+
0
Paper & Pen
 
 
 
 
==== Pre-requisites/ Instructions ====
 
 
The meaning of data and how to data is organised
 
in a tabular form
 
  
 
==== Method ====
 
 
   
 
   
The table below has spaces for up to 10 entries.
 
The first four columns have headings. Choose headings for the other
 
columns and collect data from the 10 of your class mates
 
 
                                                                                                                       
 
{| border="1"
 
|-
 
 
|  
 
|  
'''Name'''
+
0
  
 
   
 
   
 
|  
 
|  
'''Age'''
+
0
  
 
   
 
   
 +
|-
 
|  
 
|  
'''Height'''
+
'''Extras'''
  
 
   
 
   
 +
 
|  
 
|  
'''Favourite Colour '''
+
6w 1b 11lb
  
 
   
 
   
 
|  
 
|  
 
+
'''18'''
  
 
   
 
   
 +
 +
|-
 
|  
 
|  
 
+
'''Total'''
  
 
   
 
   
 +
 
|  
 
|  
 
+
for 6
  
 
   
 
   
 
|  
 
|  
 
+
'''304'''
  
 
   
 
   
|-
 
 
|  
 
|  
 
+
'''(50.0 ovs)'''
  
 
   
 
   
|  
+
|}
  
  
+
       
 +
{| border="1"
 +
|-
 +
|                                                       
 +
{| border="1"
 +
|-
 
|  
 
|  
 
+
Bowler
  
 
   
 
   
 
|  
 
|  
 
+
Overs
  
 
   
 
   
 
|  
 
|  
 
+
Maidens
  
 
   
 
   
 
|  
 
|  
 
+
Runs
  
 
   
 
   
 
|  
 
|  
 
+
Wickets
  
 
   
 
   
 +
|-
 
|  
 
|  
 
+
Bresnan
  
 
   
 
   
|-
 
 
|  
 
|  
 
+
9.0
  
 
   
 
   
 
|  
 
|  
 
+
0
  
 
   
 
   
 
|  
 
|  
 
+
62
  
 
   
 
   
 
|  
 
|  
 
+
0
  
 
   
 
   
 +
|-
 
|  
 
|  
 
+
Finn
  
 
   
 
   
 
|  
 
|  
 
+
10.0
  
 
   
 
   
 
|  
 
|  
 
+
1
  
 
   
 
   
 
|  
 
|  
 
+
44
  
 
   
 
   
|-
 
 
|  
 
|  
 
+
1
  
 
   
 
   
 +
|-
 
|  
 
|  
 
+
Dernbach
  
 
   
 
   
 
|  
 
|  
 
+
10.0
  
 
   
 
   
 
|  
 
|  
 
+
0
  
 
   
 
   
 
|  
 
|  
 
+
73
  
 
   
 
   
 
|  
 
|  
 
+
2
  
 
   
 
   
 +
|-
 
|  
 
|  
 
+
Swann
  
 
   
 
   
 
|  
 
|  
 
+
9.0
  
 
   
 
   
|-
 
 
|  
 
|  
 
+
0
  
 
   
 
   
 
|  
 
|  
 
+
34
  
 
   
 
   
 
|  
 
|  
 
+
3
  
 
   
 
   
 +
|-
 
|  
 
|  
 
+
S Patel
  
 
   
 
   
 
|  
 
|  
 
+
8.0
  
 
   
 
   
 
|  
 
|  
 
+
0
  
 
   
 
   
 
|  
 
|  
 
+
55
  
 
   
 
   
 
|  
 
|  
 
+
0
  
 
   
 
   
 
|-
 
|-
 
|  
 
|  
 
+
Bopara
  
 
   
 
   
 
|  
 
|  
 +
4.0
  
 +
 +
|
 +
0
  
 
   
 
   
 
|  
 
|  
 
+
24
  
 
   
 
   
 
|  
 
|  
 
+
0
  
 
   
 
   
|  
+
|}
  
  
 
   
 
   
 
|  
 
|  
 +
|}
  
  
 
   
 
   
|
+
== Recording Data ==
 +
 +
Let us take an example of a class which is
 +
preparing to go for a picnic. The teacher asked the students to give
 +
their choice of fruits out of banana, apple, orange or guava. Uma is
 +
asked to prepare the list. She prepared a list of all the children
 +
and wrote the choice of fruit against each name. This list would help
 +
the teacher to distribute fruits according to the choice.
  
 +
  
 
|
 
  
  
+
         
 +
{| border="1"
 
|-
 
|-
 
|  
 
|  
 +
Raghav — Banana
  
 +
 +
Preeti — Apple
  
 
   
 
   
|
+
Amar — Guava
  
 +
 +
Fatima — Orange
  
 
   
 
   
|
+
Amita — Apple
  
 +
 +
Raman — Banana
  
 
   
 
   
|
+
Radha — Orange
 
 
  
 
   
 
   
|
+
Farida — Guava
  
 +
 +
Anuradha — Banana
  
 
   
 
   
|
+
Rati — Banana
 
 
  
 
   
 
   
 
|  
 
|  
 +
Bhawana — Apple
  
 +
 +
Manoj — Banana
  
 
   
 
   
|
+
Donald — Apple
  
 +
 +
Maria — Banana
  
 
   
 
   
|-
+
Uma — Orange
|
 
  
 +
 +
Akhtar — Guava
  
 
   
 
   
|
+
Ritu — Apple
  
 +
 +
Salma — Banana
  
 
   
 
   
|
+
Kavita — Guava
 
 
  
 
   
 
   
|
+
Javed — Banana
 
 
  
 
   
 
   
|  
+
|
  
 
 
|
 
  
  
 
   
 
   
|
 
  
 
 
|
 
  
  
 
   
 
   
 +
Example 1 : A teacher
 +
wants to know the choice of food of each student as part of the
 +
mid-day meal programme. The teacher assigns the task of collecting
 +
this information to Maria. Maria does so using a paper and a pencil.
 +
After arranging the choices in a column, she puts against a choice of
 +
food one ( | ) mark for every student making that choice.
 +
 +
           
 +
{| border="1"
 
|-
 
|-
 
|  
 
|  
 
+
Choice
  
 
   
 
   
 
|  
 
|  
 
+
Number of students
  
 
   
 
   
 +
|-
 
|  
 
|  
 +
Rice only
  
 +
 +
Chapati only
  
 
   
 
   
|
+
Both rice and chapati
 
 
  
 
   
 
   
 
|  
 
|  
 +
|||||||||||||||||
  
 +
 +
|||||||||||||
  
 
   
 
   
|  
+
||||||||||||||||||||
  
 +
 +
|}
  
 
|
 
  
  
 
   
 
   
|  
+
Umesh, after seeing the
 +
table suggested a better method to count the students. He asked
 +
Maria to organise the marks ( | ) in a group of ten as shown below :
  
 
+
               
+
{| border="1"
 
|-
 
|-
 
|  
 
|  
 
+
Choice
  
 
   
 
   
 
|  
 
|  
 
+
Tally marks
  
 
   
 
   
 
|  
 
|  
 
+
Number of students
  
 
   
 
   
 +
|-
 
|  
 
|  
 +
Rice only
  
 +
 +
Chapati only
  
 
   
 
   
|
+
Both rice and chapati
 
 
  
 
   
 
   
 
|  
 
|  
 +
|||||||||| |||||||
  
 +
 +
|||||||||| |||
  
 
   
 
   
|  
+
|||||||||| ||||||||||
 
 
  
 
   
 
   
 
|  
 
|  
 +
17
  
 +
 +
13
  
 
   
 
   
|-
+
20
|
 
 
 
  
 
   
 
   
|  
+
|
  
  
 
   
 
   
|
+
Rajan made it simpler
 +
by asking her to make groups of five instead of ten, as
  
 +
 +
shown below :
  
+
                 
 +
{| border="1"
 +
|-
 
|  
 
|  
 
+
Choice
  
 
   
 
   
 
|  
 
|  
 
+
Tally marks
  
 
   
 
   
 
|  
 
|  
 
+
Number of students
  
 
   
 
   
 +
|-
 
|  
 
|  
 +
Rice only
 +
 +
 +
Chapati only
  
 +
 +
Both rice and chapati
  
 
   
 
   
 
|  
 
|  
 +
||||| |||||
 +
||||| ||
  
 +
 +
||||| |||||
 +
|||
  
 
   
 
   
|}
+
||||| ||||| ||||| |||||
  
==== Evaluation ====
 
 
   
 
   
Looking at the table
+
|
and data can the student answer the following questions ?
+
17
  
# Does any student like green the most ?
 
# Do you think red is the most popular colour, why ?
 
# What other information did you come to know about each student ?
 
 
   
 
   
== Evaluation ==
+
13
 +
 
 
   
 
   
At the end of this sub-topic the student should be
+
20
able to
 
  
 
   
 
   
# Identify the different types of data
+
|} 
# Collect, classify and organise data in a tabular form
+
 
# Calculate the frequency of data
+
 
# Interpret data that is given in a tabular form
 
 
   
 
   
== Self-Evaluation ==
+
 
 +
 
 
   
 
   
== Further Explorations ==
+
== Meaning of Frequency ==
 
   
 
   
== Enrichment Activities ==
+
Frequency means the number of occurrences within a
 +
given time period.
  
= Graphical representation of Data =
 
 
   
 
   
== Introduction ==
+
It is not easy to answer the question looking at
 +
the choices written haphazardly. We
 +
 
 
   
 
   
Tabular data
+
arrange the data in
can be also represented in the form of a picture ( charts) as visual
+
Table 1 using tally marks.
representations can sometimes be easier to interpret. There are
 
different types of pictorial representations that can be used to
 
represent different type of data.
 
  
 
   
 
   
== Objectives ==
+
Table 1
 +
 
 +
                             
 +
{| border="1"
 +
|-
 +
|
 +
Subject
 +
 
 
   
 
   
* Understand and know the different pictorial representations: Histogram, Bar Char, Pie Chart
+
|
* To be able to look at the data and select the chart that would clearly represent the data as well as convey intended information about the data.
+
Tally Marks
* Understand and know the terms : Frequency Distribution, Class intervals
+
 
* To be able to look at a graphical representation and interpret the data
 
 
   
 
   
== Histogram & Bar Chart ==
+
|
 
+
Number of Students
=== What is a histogram? ===
+
 
 
   
 
   
A histogram is a plot
+
|-
that lets you discover, and show, the underlying frequency
+
|
distribution (shape) of a set of continuous data. This allows the
+
Art
inspection of the data for its underlying distribution (e.g. normal
 
distribution), outliers, skewness, etc. An example of a histogram,
 
and the raw data it was constructed from, is shown below:
 
 
 
[[File:KOER-%20Mathematics%20-%20Statistics_html_6201ec25.png]]
 
  
 
   
 
   
36 25 38 46 55 68
+
|
72 55 36 38
+
|||| ||
  
 
   
 
   
67 45 22 48 91 46
+
|
52 61 58 55
+
7
  
 
   
 
   
=== How do you construct a histogram from a continuous variable? ===
+
|-
 +
|
 +
Mathematics
  
To construct a
 
histogram from a continuous variable you first need to split the data
 
into intervals, called bins. In the example above, age has been split
 
into bins, with each bin representing a 10-year period starting at 20
 
years. Each bin contains the number of occurrences of scores in the
 
data set that are contained within that bin. For the above data set,
 
the frequencies in each bin have been tabulated along with the scores
 
that contributed to the frequency in each bin (see below):
 
 
   
 
   
Bin Frequency Scores
+
|
Included in Bin
+
||||
  
 
   
 
   
20-30 2 25,22
+
|
 +
5
  
 
   
 
   
30-40 4 36,38,36,38
+
|-
 +
|
 +
Science
  
 
   
 
   
40-50 4 46,45,48,46
+
|
 +
|||||
  
 
   
 
   
50-60 5 55,55,52,58,55
+
|
 +
6
  
 
   
 
   
60-70 3 68,67,61
+
|-
 +
|
 +
English
  
 
   
 
   
70-80 1 72
+
|
 +
||||
  
 
   
 
   
80-90 0 -
+
|
 +
4
  
 
   
 
   
90-100 1 91
+
|}
 +
 
  
 +
 +
The number of tallies
 +
before each subject gives the number of students who like that
  
Notice that, unlike a
 
bar chart, there are no "gaps" between the bars (although
 
some bars might be "absent" reflecting no frequencies).
 
This is because a histogram represents a continuous data set, and as
 
such, there are no gaps in the data. (Although you will have to
 
decide whether you round up or round down scores on the boundaries of
 
bins)
 
 
   
 
   
=== Choosing the correct bin width ===
+
particular subject.
 +
This is known as the frequency of that subject. Frequency gives the
 +
number of times that a particular entry occurs. From Table 1,
 +
Frequency of students who like English is 4 Frequency of students
 +
who like Mathematics is 5 The table made is known as frequency
 +
distribution table as it gives the number of times an entry occurs.
 +
 
 
   
 
   
There is no right or
+
 
wrong answer as to how wide a bin should be, but there are rules of
+
 
thumb. You need to make sure that the bins are not too small or too
 
large. Consider the histogram we produced earlier (see above): the
 
following histograms use the same data but have either much smaller
 
or larger bins, as shown below:
 
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_75ab55c3.png]]
+
== Categorical Frequency Distributions ==
 
   
 
   
We can see from the
 
histogram on the left, that the bin width is too small as it shows
 
too much individual data and does not allow the underlying pattern
 
(frequency distribution) of the data to be easily seen. At the other
 
end of the scale, is the diagram on the right, where the bins are too
 
large and, again, we are unable to find the underlying trend in the
 
data.
 
  
Histograms are based on
+
 
area not height of bars
 
 
   
 
   
In a histogram, it is
+
Categorical frequency
the area of the bar that indicates the frequency of occurrences for
+
distributions - can be used for data that can be placed in specific
each bin. This means that the height of the bar does not necessarily
+
categories, such as nominal- or ordinal-level data. (nominal or
indicate how many occurrences of scores there were within each
+
ordinal also called discrete data is where we can distinctly count
individual bin. It is the product of height multiplied by the width
+
the occurences of a variable).
of the bin that indicates the frequency of occurrences within that
+
 
bin. One of the reasons that the height of the bars is often
 
incorrectly assessed as indicating frequency and not the area of the
 
bar is due to the fact that a lot of histograms often have equally
 
spaced bars (bins) and, under these circumstances, the height of the
 
bin does reflect the frequency.
 
 
   
 
   
=== What is the difference between a bar chart and a histogram? ===
+
 
 +
 
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_6dfca87b.png]]
+
Examples - political
 +
affiliation, religious affiliation, blood type etc.
  
+
                             
The major difference is
+
{| border="1"
that a histogram is only used to plot the frequency of score
+
|-
occurrences in a continuous data set that has been divided into
+
|
classes, called bins. Bar charts, on the other hand, can be used for
+
Class
a great deal of other types of variables including ordinal and
 
nominal data sets.
 
  
== Circle or Pie Chart ==
 
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_461389d1.png|800px]]
+
|  
 +
Frequency
  
These
+
are called circle graphs. A circle graph shows the relationship
+
|
between a whole and its parts. Here, the whole circle is divided into
+
Percent
sectors. The size of each sector is proportional to the activity or
 
information it represents.
 
  
 
   
 
   
A variety of graphical
+
|-
representations of data are now possible using spreadsheet software.
+
|
OpenOffice CALC can convert a table of data into bar charts, pie
+
A
charts, area charts etc and make data much more easy to
 
read/interpret.
 
  
== Activities ==
 
 
   
 
   
==== Learning Objectives Materials and Resources Required Pre-requisites/ Instructions ====
+
|
 +
5
 +
 
 
   
 
   
 +
|
 +
20
  
 +
 +
|-
 +
|
 +
B
  
 +
 +
|
 +
7
  
 
   
 
   
=== Activity 2: Histogram and Bar Chart ===
+
|
 +
28
 +
 
 
   
 
   
==== Learning Objectives ====
+
|-
+
|
Learn to draw a histogram and bar chart.
+
C
Understand the difference between a bar chart and a histogram and be
 
able to select the appropriate chart by looking at the problem and
 
data.
 
  
 
   
 
   
==== Materials and Resources Required ====
 
 
Paper and Pencil
 
 
 
==== Pre-requisites/ Instructions ====
 
 
==== Method ====
 
 
Solve the problems A and B
 
 
A> In the past year, you have recorded the
 
number of tickets that a movie theater has sold during each month.
 
To represent this data set graphically, would you construct a bar
 
graph or a histogram? Why is this choice better than the other?
 
Using the following data, construct the graph that you choose.
 
                                                 
 
{| border="1"
 
|-
 
 
|  
 
|  
Month
+
9
  
 
   
 
   
 
|  
 
|  
Number of Tickets Sold
+
36
  
 
   
 
   
 
|-
 
|-
 
|  
 
|  
January
+
D
  
 
   
 
   
 
|  
 
|  
25
+
4
  
 
   
 
   
|-
 
 
|  
 
|  
February
+
16
  
 
   
 
   
|  
+
|}
20
 
  
 
|-
 
|
 
March
 
  
 
   
 
   
|
+
Blood Type frequency
15
+
distribution example
  
 
   
 
   
|-
+
= Graphical Representations =
|
 
April
 
 
 
 
   
 
   
|
+
== Histogram & Bar Chart ==
20
+
 
 +
=== What is a histogram? ===
 +
 +
 
  
 
   
 
   
|-
+
A histogram is a plot
|
+
that lets you discover, and show, the underlying frequency
May
+
distribution (shape) of a set of continuous data. This allows the
 +
inspection of the data for its underlying distribution (e.g. normal
 +
distribution), outliers, skewness, etc. An example of a histogram,
 +
and the raw data it was constructed from, is shown below:
  
 
   
 
   
|
+
 
30
 
  
 
   
 
   
|-
+
[[Image:Statistics_html_6201ec25.png]]
|
 
June
 
  
 
   
 
   
|
+
 
35
 
  
 
   
 
   
|-
+
 
|
 
July
 
  
 
   
 
   
|
+
 
40
 
  
 
   
 
   
|-
+
 
|
 
August
 
  
 
   
 
   
|
+
 
20
 
  
 
   
 
   
|-
+
 
|
 
September
 
  
 
   
 
   
|
+
 
25
 
  
 
   
 
   
|-
+
 
|
 
October
 
  
 
   
 
   
|
+
 
15
 
  
 
   
 
   
|-
+
 
|
 
November
 
  
 
   
 
   
|
+
 
20
 
  
 
   
 
   
|-
+
 
|
 
December
 
  
 
   
 
   
|
+
 
30
 
  
 
   
 
   
|}
+
 
 +
 
 
   
 
   
B> For a recent
+
 
science project, you collected data regarding the distribution of
 
fish and aquatic life in a nearby pond. Your data consists of the
 
number of living creatures found in each 1 meter depth increment in
 
the pond. Construct a bar graph and several histograms (vary the
 
depth increment size) for the following data. In which case(s) is the
 
histogram the same as the bar graph? How do the other histograms vary
 
from the bar graph?
 
                                               
 
{| border="1"
 
|-
 
|
 
'''Depth Range'''
 
  
 
   
 
   
|
+
 
'''Number of Living Creatures '''
 
  
 
   
 
   
|-
+
36 25 38 46 55 68
|
+
72 55 36 38
0 – 1 meters
 
  
 
   
 
   
|
+
67 45 22 48 91 46
10
+
52 61 58 55
  
 
   
 
   
|-
+
=== How do you construct a histogram from a continuous variable? ===
|
+
1 – 2 meters
+
 
  
 
   
 
   
|
+
To construct a
93
+
histogram from a continuous variable you first need to split the data
 +
into intervals, called bins. In the example above, age has been split
 +
into bins, with each bin representing a 10-year period starting at 20
 +
years. Each bin contains the number of occurrences of scores in the
 +
data set that are contained within that bin. For the above data set,
 +
the frequencies in each bin have been tabulated along with the scores
 +
that contributed to the frequency in each bin (see below):
  
 
   
 
   
|-
 
|
 
2 – 3 meters
 
  
 
|
 
23
 
  
 
   
 
   
|-
+
Bin Frequency Scores
|
+
Included in Bin
3 – 4 meters
 
  
 
   
 
   
|
+
20-30 2 25,22
47
 
  
 
   
 
   
|-
+
30-40 4 36,38,36,38
|
 
4 – 5 meters
 
  
 
   
 
   
|
+
40-50 4 46,45,48,46
68
 
  
 
   
 
   
|-
+
50-60 5 55,55,52,58,55
|
 
5 – 6 meters
 
  
 
   
 
   
|
+
60-70 3 68,67,61
51
 
  
 
   
 
   
|-
+
70-80 1 72
|
 
6 – 7 meters
 
  
 
   
 
   
|
+
80-90 0 -
43
 
  
 
   
 
   
|-
+
90-100 1 91
|
 
7 – 8 meters
 
  
 
   
 
   
|
 
21
 
  
 
|-
 
|
 
8 – 9 meters
 
  
 
   
 
   
|
+
Notice that, unlike a
15
+
bar chart, there are no "gaps" between the bars (although
 +
some bars might be "absent" reflecting no frequencies).
 +
This is because a histogram represents a continuous data set, and as
 +
such, there are no gaps in the data. (Although you will have to
 +
decide whether you round up or round down scores on the boundaries of
 +
bins)
  
 
   
 
   
|-
 
|
 
9 – 10 meters
 
  
 
|
 
8
 
  
 
   
 
   
|}
+
=== Choosing the correct bin width ===
==== Evaluation ====
 
 
   
 
   
# Does the student understand the difference between a bar chart and a histogram ?
 
# Does the student know when to use each of these charts - - depending on the type of data continuous and discrete ?
 
  
== Evaluation ==
+
 
 
   
 
   
== Self-Evaluation ==
+
There is no right or
 +
wrong answer as to how wide a bin should be, but there are rules of
 +
thumb. You need to make sure that the bins are not too small or too
 +
large. Consider the histogram we produced earlier (see above): the
 +
following histograms use the same data but have either much smaller
 +
or larger bins, as shown below:
 +
 
 
   
 
   
== Further Explorations ==
+
 
 +
 
 
   
 
   
=== Types of Variables ===
+
[[Image:Statistics_html_75ab55c3.png]]
 +
 
 
   
 
   
All experiments examine some kind of variable(s).
 
A variable is not only something that we measure, but also something
 
that we can manipulate and something we can control for. To
 
understand the characteristics of variables and how we use them in
 
research, this guide is divided into three main sections. First, we
 
illustrate the role of dependent and independent variables. Second,
 
we discuss the difference between experimental and non-experimental
 
research. Finally, we explain how variables can be characterised as
 
either categorical or continuous.
 
  
=== Dependent and Independent Variables ===
 
  
An independent variable, sometimes called an
+
experimental or predictor variable, is a variable that is being
 
manipulated in an experiment in order to observe the effect on a
 
dependent variable, sometimes called an outcome variable.
 
  
Imagine that a tutor asks 100 students to complete
 
a maths test. The tutor wants to know why some students perform
 
better than others. Whilst the tutor does not know the answer to
 
this, she thinks that it might be because of two reasons: (1) some
 
students spend more time revising for their test; and (2) some
 
students are naturally more intelligent than others. As such, the
 
tutor decides to investigate the effect of revision time and
 
intelligence on the test performance of the 100 students. The
 
dependent and independent variables for the study are:
 
  
Dependent Variable: Test Mark (measured from 0 to
+
100)
+
We can see from the
 +
histogram on the left, that the bin width is too small as it shows
 +
too much individual data and does not allow the underlying pattern
 +
(frequency distribution) of the data to be easily seen. At the other
 +
end of the scale, is the diagram on the right, where the bins are too
 +
large and, again, we are unable to find the underlying trend in the
 +
data.
 +
 
 +
 +
Histograms are based on
 +
area not height of bars
  
Independent Variables: Revision time (measured in
 
hours) Intelligence (measured using IQ score)
 
 
   
 
   
The dependent variable is simply that, a variable
 
that is dependent on an independent variable(s). For example, in our
 
case the test mark that a student achieves is dependent on revision
 
time and intelligence. Whilst revision time and intelligence (the
 
independent variables) may (or may not) cause a change in the test
 
mark (the dependent variable), the reverse is implausible; in other
 
words, whilst the number of hours a student spends revising and the
 
higher a student's IQ score may (or may not) change the test mark
 
that a student achieves, a change in a student's test mark has no
 
bearing on whether a student revises more or is more intelligent
 
(this simply doesn't make sense).
 
  
Therefore, the aim of the tutor's investigation is
 
to examine whether these independent variables - revision time and IQ
 
- result in a change in the dependent variable, the students' test
 
scores. However, it is also worth noting that whilst this is the main
 
aim of the experiment, the tutor may also be interested to know if
 
the independent variables - revision time and IQ - are also connected
 
in some way.
 
  
In the section on experimental and
+
non-experimental research that follows, we find out a little more
+
In a histogram, it is
about the nature of independent and dependent variables.
+
the area of the bar that indicates the frequency of occurrences for
 +
each bin. This means that the height of the bar does not necessarily
 +
indicate how many occurrences of scores there were within each
 +
individual bin. It is the product of height multiplied by the width
 +
of the bin that indicates the frequency of occurrences within that
 +
bin. One of the reasons that the height of the bars is often
 +
incorrectly assessed as indicating frequency and not the area of the
 +
bar is due to the fact that a lot of histograms often have equally
 +
spaced bars (bins) and, under these circumstances, the height of the
 +
bin does reflect the frequency.
 +
 
 +
 +
 
  
 
   
 
   
=== Experimental and Non-Experimental Research ===
+
=== What is the difference between a bar chart and a histogram? ===
 +
 +
[[Image:Statistics_html_6dfca87b.png]]
 +
 
 
   
 
   
Experimental research: In experimental research,
+
The major difference is
the aim is to manipulate an independent variable(s) and then examine
+
that a histogram is only used to plot the frequency of score
the effect that this change has on a dependent variable(s). Since it
+
occurrences in a continuous data set that has been divided into
is possible to manipulate the independent variable(s), experimental
+
classes, called bins. Bar charts, on the other hand, can be used for
research has the advantage of enabling a researcher to identify a
+
a great deal of other types of variables including ordinal and
cause and effect between variables. For example, take our example of
+
nominal data sets.
100 students completing a maths exam where the dependent variable was
+
 
the exam mark (measured from 0 to 100) and the independent variables
+
were revision time (measured in hours) and intelligence (measured
+
 
using IQ score). Here, it would be possible to use an experimental
+
 
design and manipulate the revision time of the students. The tutor
 
could divide the students into two groups, each made up of 50
 
students. In "group one", the tutor could ask the students
 
not to do any revision. Alternately, "group two" could be
 
asked to do 20 hours of revision in the two weeks prior to the test.
 
The tutor could then compare the marks that the students achieved.
 
 
   
 
   
Non-experimental research: In non-experimental
+
 
research, the researcher does not manipulate the independent
+
 
variable(s). This is not to say that it is impossible to do so, but
 
it will either be impractical or unethical to do so. For example, a
 
researcher may be interested in the effect of illegal, recreational
 
drug use (the dependent variable(s)) on certain types of behaviour
 
(the independent variable(s)). However, whilst possible, it would be
 
unethical to ask individuals to take illegal drugs in order to study
 
what effect this had on certain behaviours. As such, a researcher
 
could ask both drug and non-drug users to complete a questionnaire
 
that had been constructed to indicate the extent to which they
 
exhibited certain behaviours. Whilst it is not possible to identify
 
the cause and effect between the variables, we can still examine the
 
association or relationship between them.In addition to understanding
 
the difference between dependent and independent variables, and
 
experimental and non-experimental research, it is also important to
 
understand the different characteristics amongst variables. This is
 
discussed next.
 
 
   
 
   
=== Categorical and Continuous Variables ===
 
  
Categorical variables are also known as discrete
+
 
or qualitative variables. Categorical variables can be further
 
categorized as either''' nominal, ordinal or dichotomous.'''
 
 
   
 
   
'''Nominal variables''' are variables that have
+
== Circle or Pie Chart ==
two or more categories but which do not have an intrinsic order. For
 
example, a real estate agent could classify their types of property
 
into distinct categories such as houses, condos, co-ops or bungalows.
 
So "type of property" is a nominal variable with 4
 
categories called houses, condos, co-ops and bungalows. Of note, the
 
different categories of a nominal variable can also be referred to as
 
groups or levels of the nominal variable. Another example of a
 
nominal variable would be classifying where people live in Karnataka
 
by district. In this case there will be many more levels of the
 
nominal variable (30 in fact).
 
 
   
 
   
'''Dichotomous variables''' are nominal
 
variables which have only two categories or levels. For example, if
 
we were looking at gender, we would most probably categorize somebody
 
as either "male" or "female". This is an example
 
of a dichotomous variable (and also a nominal variable). Another
 
example might be if we asked a person if they owned a mobile phone.
 
Here, we may categorise mobile phone ownership as either "Yes"
 
or "No". In the real estate agent example, if type of
 
property had been classified as either residential or commercial then
 
"type of property" would be a dichotomous variable.
 
  
'''Ordinal variables''' are variables that have
+
 
two or more categories just like nominal variables only the
 
categories can also be ordered or ranked. So if you asked someone if
 
they liked the policies of the Democratic Party and they could answer
 
either "Not very much", "They are OK" or "Yes,
 
a lot" then you have an ordinal variable. Why? Because you have
 
3 categories, namely "Not very much", "They are OK"
 
and "Yes, a lot" and you can rank them from the most
 
positive (Yes, a lot), to the middle response (They are OK), to the
 
least positive (Not very much). However, whilst we can rank the
 
levels, we cannot place a "value" to them; we cannot say
 
that "They are OK" is twice as positive as "Not very
 
much" for example.
 
 
   
 
   
Continuous variables are also known as
+
These are called circle
quantitative variables. Continuous variables can be further
+
graphs. A circle graph shows the relationship between a whole and its
categorized as either interval or ratio variables.
+
parts. Here, the whole circle is divided into sectors. The size of
 +
each sector is proportional to the activity or information it
 +
represents.
 +
 
 
   
 
   
'''Interval variables''' are variables for which
+
 
their central characteristic is that they can be measured along a
+
 
continuum and they have a numerical value (for example, temperature
 
measured in degrees Celsius or Fahrenheit). So the difference between
 
20C and 30C is the same as 30C to 40C. However, temperature measured
 
in degrees Celsius or Fahrenheit is NOT a ratio variable.
 
 
   
 
   
'''Ratio variables''' are interval variables but
+
A variety of graphical
with the added condition that 0 (zero) of the measurement indicates
+
representations of data are now possible using spreadsheet software.
that there is none of that variable. So, temperature measured in
+
OpenOffice CALC can convert a table of data into bar charts, pie
degrees Celsius or Fahrenheit is not a ratio variable because 0C does
+
charts, area charts etc and make data much more easy to
not mean there is no temperature. However, temperature measured in
+
read/interpret.
Kelvin is a ratio variable as 0 Kelvin (often called absolute zero)
+
 
indicates that there is no temperature whatsoever. Other examples of
 
ratio variables include height, mass, distance and many more. The
 
name "ratio" reflects the fact that you can use the ratio
 
of measurements. So, for example, a distance of ten metres is twice
 
the distance of 5 metres.
 
 
   
 
   
=== Ambiguities in classifying a type of variable ===
 
  
In some cases, the measurement scale for data is
 
ordinal but the variable is treated as continuous. For example, a
 
Likert scale that contains five values - strongly agree, agree,
 
neither agree nor disagree, disagree, and strongly disagree - is
 
ordinal. However, where a Likert scale contains seven or more value -
 
strongly agree, moderately agree, agree, neither agree nor disagree,
 
disagree, moderately disagree, and strongly disagree - the underlying
 
scale is sometimes treated as continuous although where you should do
 
this is a cause of great dispute.
 
  
It is worth noting that how we categorise
+
   
variables is somewhat of a choice. Whilst we categorised gender as a
+
= Types of Variables =
dichotomous variable (you are either male or female), social
+
scientists may disagree with this, arguing that gender is a more
+
All experiments examine some kind of variable(s).
complex variable involving more than two distinctions, but also
+
A variable is not only something that we measure, but also something
including measurement levels like genderqueer, intersex, and
+
that we can manipulate and something we can control for. To
transgender. At the same time, some researchers would argue that a
+
understand the characteristics of variables and how we use them in
Likert scale, even with seven values, should never be treated as a
+
research, this guide is divided into three main sections. First, we
continuous variable.
+
illustrate the role of dependent and independent variables. Second,
 +
we discuss the difference between experimental and non-experimental
 +
research. Finally, we explain how variables can be characterised as
 +
either categorical or continuous.
  
== Enrichment Activities ==
 
 
   
 
   
= Central tendency =
+
== Dependent and Independent Variables ==
 
   
 
   
== Introduction ==
+
 
 +
 
 +
 
 
   
 
   
A measure of central tendency is a single value
+
An independent variable, sometimes called an
that attempts to describe a set of data by identifying the central
+
experimental or predictor variable, is a variable that is being
position within that set of data. As such, measures of central
+
manipulated in an experiment in order to observe the effect on a
tendency are sometimes called measures of central location. They are
+
dependent variable, sometimes called an outcome variable.
also classed as summary statistics. The mean (often called the
 
average) is most likely the measure of central tendency that you are
 
most familiar with, but there are others, such as, the median and the
 
mode.
 
  
 
   
 
   
The mean, median and mode are all valid measures
+
 
of central tendency but, under different conditions, some measures of
+
 
central tendency become more appropriate to use than others. In the
 
following sections we will look at the mean, mode and median and
 
learn how to calculate them and under what conditions they are most
 
appropriate to be used.
 
  
 
   
 
   
== Objectives ==
+
Imagine that a tutor asks 100 students to complete
+
a maths test. The tutor wants to know why some students perform
* Understand and know that a measure of central tendency is a single value that attempts to describe a set of data by identifying the central position within that set of data.
+
better than others. Whilst the tutor does not know the answer to
* Understand that the mean, median and mode are all valid measures of central tendency but, under different conditions, some measures of central tendency become more appropriate to use than others.
+
this, she thinks that it might be because of two reasons: (1) some
* Learn to calculation of mean and median and analyse data and make conclusions.
+
students spend more time revising for their test; and (2) some
+
students are naturally more intelligent than others. As such, the
== Mean (Arithmetic) ==
+
tutor decides to investigate the effect of revision time and
 +
intelligence on the test performance of the 100 students. The
 +
dependent and independent variables for the study are:
 +
 
 
   
 
   
The mean (or average) is the most popular and well
+
 
known measure of central tendency. It can be used with both discrete
+
 
and continuous data, although its use is most often with continuous
+
 
data. The mean is equal to the sum of all the values in the data set
 
divided by the number of values in the data set. So, if we have n
 
values in a data set and they have values x<sub>1</sub>, x<sub>2</sub>,
 
..., x<sub>n</sub>, then the sample mean, usually denoted by
 
[[File:KOER-%20Mathematics%20-%20Statistics_html_174cec39.gif]]
 
(pronounced x bar), is:
 
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_69b2cf9e.gif]]
+
Dependent Variable: Test Mark (measured from 0 to
 +
100)
  
 
   
 
   
This formula is usually written in a slightly
+
 
different manner using the Greek capitol letter, Σ,
+
 
pronounced &quot;sigma&quot;, which means &quot;sum of...&quot;:
 
  
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_m50e9a786.gif]]
+
Independent Variables: Revision time (measured in
 +
hours) Intelligence (measured using IQ score)
  
 
   
 
   
You may have noticed that the above formula refers
 
to the sample mean. So, why call have we called it a sample mean?
 
This is because, in statistics, samples and populations have very
 
different meanings and these differences are very important, even if,
 
in the case of the mean, they are calculated in the same way. To
 
acknowledge that we are calculating the population mean and not the
 
sample mean, we use the Greek lower case letter &quot;mu&quot;,
 
denoted as µ:
 
  
+
 
[[File:KOER-%20Mathematics%20-%20Statistics_html_7b1e9596.gif]]
 
  
 
   
 
   
The mean is essentially a model of your data set.
+
The dependent variable is simply that, a variable
It is the value that is most common. You will notice, however, that
+
that is dependent on an independent variable(s). For example, in our
the mean is not often one of the actual values that you have observed
+
case the test mark that a student achieves is dependent on revision
in your data set. However, one of its important properties is that it
+
time and intelligence. Whilst revision time and intelligence (the
minimises error in the prediction of any one value in your data set.
+
independent variables) may (or may not) cause a change in the test
That is, it is the value that produces the lowest amount of error
+
mark (the dependent variable), the reverse is implausible; in other
from all other values in the data set.
+
words, whilst the number of hours a student spends revising and the
 +
higher a student's IQ score may (or may not) change the test mark
 +
that a student achieves, a change in a student's test mark has no
 +
bearing on whether a student revises more or is more intelligent
 +
(this simply doesn't make sense).
  
 
   
 
   
An important property of the mean is that it
 
includes every value in your data set as part of the calculation. In
 
addition, the mean is the only measure of central tendency where the
 
sum of the deviations of each value from the mean is always zero.
 
 
'''When not to use the mean'''
 
  
 
The mean has one main disadvantage: it is
 
particularly susceptible to the influence of outliers. These are
 
values that are unusual compared to the rest of the data set by being
 
especially small or large in numerical value. For example, consider
 
the wages of staff at a factory below:
 
  
                                     
 
{| border="1"
 
|-
 
|
 
Staff
 
  
 
   
 
   
|
+
Therefore, the aim of the tutor's investigation is
1
+
to examine whether these independent variables - revision time and IQ
 +
- result in a change in the dependent variable, the students' test
 +
scores. However, it is also worth noting that whilst this is the main
 +
aim of the experiment, the tutor may also be interested to know if
 +
the independent variables - revision time and IQ - are also connected
 +
in some way.
  
 
   
 
   
|
 
2
 
  
 
|
 
3
 
  
 
|
 
4
 
  
 
   
 
   
|
+
In the section on experimental and
5
+
non-experimental research that follows, we find out a little more
 +
about the nature of independent and dependent variables.
  
 
   
 
   
|
 
6
 
  
 
|
 
7
 
  
 
|
 
8
 
  
 
   
 
   
|
+
== Experimental and Non-Experimental Research ==
9
 
 
 
 
   
 
   
|
 
10
 
  
 
|-
 
|
 
Salary
 
  
 
|
 
15k
 
  
 
   
 
   
|
+
Experimental research: In experimental research,
18k
+
the aim is to manipulate an independent variable(s) and then examine
 +
the effect that this change has on a dependent variable(s). Since it
 +
is possible to manipulate the independent variable(s), experimental
 +
research has the advantage of enabling a researcher to identify a
 +
cause and effect between variables. For example, take our example of
 +
100 students completing a maths exam where the dependent variable was
 +
the exam mark (measured from 0 to 100) and the independent variables
 +
were revision time (measured in hours) and intelligence (measured
 +
using IQ score). Here, it would be possible to use an experimental
 +
design and manipulate the revision time of the students. The tutor
 +
could divide the students into two groups, each made up of 50
 +
students. In &quot;group one&quot;, the tutor could ask the students
 +
not to do any revision. Alternately, &quot;group two&quot; could be
 +
asked to do 20 hours of revision in the two weeks prior to the test.
 +
The tutor could then compare the marks that the students achieved.
  
 
   
 
   
|
+
Non-experimental research: In non-experimental
16k
+
research, the researcher does not manipulate the independent
 +
variable(s). This is not to say that it is impossible to do so, but
 +
it will either be impractical or unethical to do so. For example, a
 +
researcher may be interested in the effect of illegal, recreational
 +
drug use (the dependent variable(s)) on certain types of behaviour
 +
(the independent variable(s)). However, whilst possible, it would be
 +
unethical to ask individuals to take illegal drugs in order to study
 +
what effect this had on certain behaviours. As such, a researcher
 +
could ask both drug and non-drug users to complete a questionnaire
 +
that had been constructed to indicate the extent to which they
 +
exhibited certain behaviours. Whilst it is not possible to identify
 +
the cause and effect between the variables, we can still examine the
 +
association or relationship between them.In addition to understanding
 +
the difference between dependent and independent variables, and
 +
experimental and non-experimental research, it is also important to
 +
understand the different characteristics amongst variables. This is
 +
discussed next.
  
 
   
 
   
|
+
 
14k
+
 
  
 
   
 
   
|
+
=== Categorical and Continuous Variables ===
15k
+
 +
 
 +
 
  
 
   
 
   
|
+
Categorical variables are also known as discrete
15k
+
or qualitative variables. Categorical variables can be further
 +
categorized as either''' nominal, ordinal or dichotomous.'''
  
 
   
 
   
|
 
12k
 
  
 
|
 
17k
 
  
 
|
 
90k
 
  
 
   
 
   
|
+
'''Nominal variables''' are variables that have
95k
+
two or more categories but which do not have an intrinsic order. For
 +
example, a real estate agent could classify their types of property
 +
into distinct categories such as houses, condos, co-ops or bungalows.
 +
So &quot;type of property&quot; is a nominal variable with 4
 +
categories called houses, condos, co-ops and bungalows. Of note, the
 +
different categories of a nominal variable can also be referred to as
 +
groups or levels of the nominal variable. Another example of a
 +
nominal variable would be classifying where people live in USA by
 +
state. In this case there will be many more levels of the nominal
 +
variable (50 in fact).
  
 
   
 
   
|}
+
'''Dichotomous variables''' are nominal
The mean salary for these ten staff is $30.7k.
+
variables which have only two categories or levels. For example, if
However, inspecting the raw data suggests that this mean value might
+
we were looking at gender, we would most probably categorize somebody
not be the best way to accurately reflect the typical salary of a
+
as either &quot;male&quot; or &quot;female&quot;. This is an example
worker, as most workers have salaries in the $12k to 18k range. The
+
of a dichotomous variable (and also a nominal variable). Another
mean is being skewed by the two large salaries. Therefore, in this
+
example might be if we asked a person if they owned a mobile phone.
situation we would like to have a better measure of central tendency.
+
Here, we may categorise mobile phone ownership as either &quot;Yes&quot;
As we will find out later, taking the median would be a better
+
or &quot;No&quot;. In the real estate agent example, if type of
measure of central tendency in this situation.
+
property had been classified as either residential or commercial then
 +
&quot;type of property&quot; would be a dichotomous variable.
  
 
   
 
   
Another time when we usually prefer the median
+
'''Ordinal variables''' are variables that have
over the mean (or mode) is when our data is skewed (i.e. the
+
two or more categories just like nominal variables only the
frequency distribution for our data is skewed). If we consider the
+
categories can also be ordered or ranked. So if you asked someone if
normal distribution - as this is the most frequently assessed in
+
they liked the policies of the Democratic Party and they could answer
statistics - when the data is perfectly normal then the mean, median
+
either &quot;Not very much&quot;, &quot;They are OK&quot; or &quot;Yes,
and mode are identical. Moreover, they all represent the most typical
+
a lot&quot; then you have an ordinal variable. Why? Because you have
value in the data set. However, as the data becomes skewed the mean
+
3 categories, namely &quot;Not very much&quot;, &quot;They are OK&quot;
loses its ability to provide the best central location for the data
+
and &quot;Yes, a lot&quot; and you can rank them from the most
as the skewed data is dragging it away from the typical value.
+
positive (Yes, a lot), to the middle response (They are OK), to the
However, the median best retains this position and is not as strongly
+
least positive (Not very much). However, whilst we can rank the
influenced by the skewed values. This is explained in more detail in
+
levels, we cannot place a &quot;value&quot; to them; we cannot say
the skewed distribution section later in this guide.
+
that &quot;They are OK&quot; is twice as positive as &quot;Not very
 +
much&quot; for example.
  
== Median ==
 
 
   
 
   
The median is the middle score for a set of data
 
that has been arranged in order of magnitude. The median is less
 
affected by outliers and skewed data. In order to calculate the
 
median, suppose we have the data below:
 
                         
 
{| border="1"
 
|-
 
|
 
65
 
  
+
 
|
 
55
 
  
 
   
 
   
|
+
Continuous variables are also known as
89
+
quantitative variables. Continuous variables can be further
 +
categorized as either interval or ratio variables.
  
 
   
 
   
|
 
56
 
  
 
|
 
35
 
  
 
|
 
14
 
  
 
   
 
   
|
+
'''Interval variables''' are variables for which
56
+
their central characteristic is that they can be measured along a
 +
continuum and they have a numerical value (for example, temperature
 +
measured in degrees Celsius or Fahrenheit). So the difference between
 +
20C and 30C is the same as 30C to 40C. However, temperature measured
 +
in degrees Celsius or Fahrenheit is NOT a ratio variable.
  
 
   
 
   
|
+
'''Ratio variables''' are interval variables but
55
+
with the added condition that 0 (zero) of the measurement indicates
 
+
that there is none of that variable. So, temperature measured in
+
degrees Celsius or Fahrenheit is not a ratio variable because 0C does
|
+
not mean there is no temperature. However, temperature measured in
87
+
Kelvin is a ratio variable as 0 Kelvin (often called absolute zero)
 +
indicates that there is no temperature whatsoever. Other examples of
 +
ratio variables include height, mass, distance and many more. The
 +
name &quot;ratio&quot; reflects the fact that you can use the ratio
 +
of measurements. So, for example, a distance of ten metres is twice
 +
the distance of 5 metres.
  
 
   
 
   
|
 
45
 
  
 
|
 
92
 
  
 
|}
 
  
 
   
 
   
We first need to rearrange that data into order of
+
=== Ambiguities in classifying a type of variable ===
magnitude (smallest first):
 
                         
 
{| border="1"
 
|-
 
|
 
14
 
 
 
 
   
 
   
|
 
35
 
  
 
|
 
45
 
  
 
|
 
55
 
  
 
   
 
   
|
+
In some cases, the measurement scale for data is
55
+
ordinal but the variable is treated as continuous. For example, a
 +
Likert scale that contains five values - strongly agree, agree,
 +
neither agree nor disagree, disagree, and strongly disagree - is
 +
ordinal. However, where a Likert scale contains seven or more value -
 +
strongly agree, moderately agree, agree, neither agree nor disagree,
 +
disagree, moderately disagree, and strongly disagree - the underlying
 +
scale is sometimes treated as continuous although where you should do
 +
this is a cause of great dispute.
  
 
   
 
   
|
 
'''56'''
 
  
 
|
 
56
 
  
 
|
 
65
 
  
 
   
 
   
|
+
It is worth noting that how we categorise
87
+
variables is somewhat of a choice. Whilst we categorised gender as a
 +
dichotomous variable (you are either male or female), social
 +
scientists may disagree with this, arguing that gender is a more
 +
complex variable involving more than two distinctions, but also
 +
including measurement levels like genderqueer, intersex, and
 +
transgender. At the same time, some researchers would argue that a
 +
Likert scale, even with seven values, should never be treated as a
 +
continuous variable.
  
 
   
 
   
|
+
= Central Tendency =
89
 
 
 
 
   
 
   
|
 
92
 
  
 
|}
 
  
Our median mark is the middle mark - in this case
 
56 (highlighted in bold). It is the middle mark because there are 5
 
scores before it and 5 scores after it. This works fine when you have
 
an odd number of scores but what happens when you have an even number
 
of scores? What if you had only 10 scores? Well, you simply have to
 
take the middle two scores and average the result. So, if we look at
 
the example below:
 
  
                   
+
{| border="1"
+
== Introduction ==
|-
+
|
+
A measure of central tendency is a single value
65
+
that attempts to describe a set of data by identifying the central
 +
position within that set of data. As such, measures of central
 +
tendency are sometimes called measures of central location. They are
 +
also classed as summary statistics. The mean (often called the
 +
average) is most likely the measure of central tendency that you are
 +
most familiar with, but there are others, such as, the median and the
 +
mode.
  
 
   
 
   
|
+
The mean, median and mode are all valid measures
55
+
of central tendency but, under different conditions, some measures of
 +
central tendency become more appropriate to use than others. In the
 +
following sections we will look at the mean, mode and median and
 +
learn how to calculate them and under what conditions they are most
 +
appropriate to be used.
  
 
   
 
   
|
+
== Mean (Arithmetic) ==
89
 
 
 
 
   
 
   
|
+
The mean (or average) is the most popular and well
56
+
known measure of central tendency. It can be used with both discrete
 +
and continuous data, although its use is most often with continuous
 +
data. The mean is equal to the sum of all the values in the data set
 +
divided by the number of values in the data set. So, if we have n
 +
values in a data set and they have values x<sub>1</sub>, x<sub>2</sub>,
 +
..., x<sub>n</sub>, then the sample mean, usually denoted by
 +
[[Image:Statistics_html_174cec39.gif]]
 +
(pronounced x bar), is:
  
 
   
 
   
|
 
35
 
  
 
|
 
14
 
  
 
|
 
56
 
  
 
   
 
   
|
+
[[Image:Statistics_html_69b2cf9e.gif]]
55
 
  
 
   
 
   
|
+
This formula is usually written in a slightly
87
+
different manner using the Greek capitol letter, Σ,
 +
pronounced &quot;sigma&quot;, which means &quot;sum of...&quot;:
  
 
   
 
   
|
+
[[Image:Statistics_html_m50e9a786.gif]]
45
 
  
 
   
 
   
|}
+
You may have noticed that the above formula refers
 
+
to the sample mean. So, why call have we called it a sample mean?
We again rearrange that data into order of
+
This is because, in statistics, samples and populations have very
magnitude (smallest first):
+
different meanings and these differences are very important, even if,
                         
+
in the case of the mean, they are calculated in the same way. To
{| border="1"
+
acknowledge that we are calculating the population mean and not the
|-
+
sample mean, we use the Greek lower case letter &quot;mu&quot;,
|
+
denoted as µ:
14
 
  
 
   
 
   
|
+
[[Image:Statistics_html_7b1e9596.gif]]
35
 
  
 
   
 
   
|
+
The mean is essentially a model of your data set.
45
+
It is the value that is most common. You will notice, however, that
 +
the mean is not often one of the actual values that you have observed
 +
in your data set. However, one of its important properties is that it
 +
minimises error in the prediction of any one value in your data set.
 +
That is, it is the value that produces the lowest amount of error
 +
from all other values in the data set.
 +
 
 +
 +
An important property of the mean is that it
 +
includes every value in your data set as part of the calculation. In
 +
addition, the mean is the only measure of central tendency where the
 +
sum of the deviations of each value from the mean is always zero.
  
 
   
 
   
|
+
 
55
+
 
  
 
   
 
   
|
+
'''When not to use the mean'''
'''55'''
 
  
 
   
 
   
 +
The mean has one main disadvantage: it is
 +
particularly susceptible to the influence of outliers. These are
 +
values that are unusual compared to the rest of the data set by being
 +
especially small or large in numerical value. For example, consider
 +
the wages of staff at a factory below:
 +
 +
                                     
 +
{| border="1"
 +
|-
 
|  
 
|  
'''56'''
+
Staff
  
 
   
 
   
 
|  
 
|  
56
+
1
  
 
   
 
   
 
|  
 
|  
65
+
2
  
 
   
 
   
 
|  
 
|  
87
+
3
  
 
   
 
   
 
|  
 
|  
89
+
4
  
 
   
 
   
 
|  
 
|  
92
+
5
  
 
   
 
   
|}
+
|  
 +
6
  
 +
 +
|
 +
7
  
Only now we have to take the 5th and 6th score in
+
our data set and average them to get a median of 55.5.
+
|
 +
8
  
== Mode ==
 
 
   
 
   
The mode is the most frequent score in our data
+
|
set. On a histogram it represents the highest bar in a bar chart or
+
9
histogram. You can, therefore, sometimes consider the mode as being
 
the most popular option. An example of a mode is presented below:
 
  
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_58d59706.png]]
+
|
 +
10
 +
 
 
   
 
   
Normally, the mode is used for categorical data
+
|-
where we wish to know which is the most common category as
+
|
illustrated below:
+
Salary
  
 
   
 
   
We can see above that the most common form of
+
|
transport, in this particular data set, is the bus. However, one of
+
15k
the problems with the mode is that it is not unique, so it leaves us
+
 
with problems when we have two or more values that share the highest
 
frequency, such as below:
 
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_m64bbad46.png]]
+
|
 +
18k
 +
 
 
   
 
   
We are now stuck as to which mode best describes
+
|
the central tendency of the data. This is particularly problematic
+
16k
when we have continuous data, as we are more likely not to have any
 
one value that is more frequent than the other. For example, consider
 
measuring 30 peoples' weight (to the nearest 0.1 kg). How likely is
 
it that we will find two or more people with '''exactly'''
 
the same weight, e.g. 67.4 kg? The answer, is probably very unlikely
 
- many people might be close but with such a small sample (30 people)
 
and a large range of possible weights you are unlikely to find two
 
people with exactly the same weight, that is, to the nearest 0.1 kg.
 
This is why the mode is very rarely used with continuous data.
 
  
Another problem with the mode is that it will not
 
provide us with a very good measure of central tendency when the most
 
common mark is far away from the rest of the data in the data set, as
 
depicted in the diagram below:
 
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_152dd141.png]]
+
|
 +
14k
  
In the above diagram the mode has a value of 2. We
+
can clearly see, however, that the mode is not representative of the
+
|
data, which is mostly concentrated around the 20 to 30 value range.
+
15k
To use the mode to describe the central tendency of this data set
 
would be misleading.
 
  
== Skewed Distributions and the Mean and Median ==
 
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_26c6186d.png]]
+
|
 +
15k
  
We often test whether our data is normally distributed as this is a
+
common assumption underlying many statistical tests. An example of a
+
|
normally distributed set of data is presented below:
+
12k
  
When you have a normally distributed sample you
+
can legitimately use both the mean or the median as your measure of
+
|
central tendency. In fact, in any symmetrical distribution the mean,
+
17k
median and mode are equal. However, in this situation, the mean is
 
widely preferred as the best measure of central tendency as it is the
 
measure that includes all the values in the data set for its
 
calculation, and any change in any of the scores will affect the
 
value of the mean. This is not the case with the median or mode.
 
  
 
   
 
   
However, when our data is skewed, for example, as
+
|
with the right-skewed data set below:
+
90k
  
 
[[File:KOER-%20Mathematics%20-%20Statistics_html_m2609c500.png]]
 
 
   
 
   
we find that the mean is being dragged in the
+
|
direct of the skew. In these situations, the median is generally
+
95k
considered to be the best representative of the central location of
 
the data. The more skewed the distribution the greater the difference
 
between the median and mean, and the greater emphasis should be
 
placed on using the median as opposed to the mean. A classic example
 
of the above right-skewed distribution is income (salary), where
 
higher-earners provide a false representation of the typical income
 
if expressed as a mean and not a median.
 
  
 
   
 
   
If dealing with a normal distribution, and tests
+
|}
of normality show that the data is non-normal, then it is customary
+
The mean salary for these ten staff is $30.7k.
to use the median instead of the mean. This is more a rule of thumb
+
However, inspecting the raw data suggests that this mean value might
than a strict guideline however. Sometimes, researchers wish to
+
not be the best way to accurately reflect the typical salary of a
report the mean of a skewed distribution if the median and mean are
+
worker, as most workers have salaries in the $12k to 18k range. The
not appreciably different (a subjective assessment) and if it allows
+
mean is being skewed by the two large salaries. Therefore, in this
easier comparisons to previous research to be made.
+
situation we would like to have a better measure of central tendency.
 +
As we will find out later, taking the median would be a better
 +
measure of central tendency in this situation.
  
== Summary of when to use the mean, median and mode ==
 
 
   
 
   
Please use the following summary table to know
+
Another time when we usually prefer the median
what the best measure of central tendency is with respect to the
+
over the mean (or mode) is when our data is skewed (i.e. the
different types of variables.
+
frequency distribution for our data is skewed). If we consider the
                       
+
normal distribution - as this is the most frequently assessed in
 +
statistics - when the data is perfectly normal then the mean, median
 +
and mode are identical. Moreover, they all represent the most typical
 +
value in the data set. However, as the data becomes skewed the mean
 +
loses its ability to provide the best central location for the data
 +
as the skewed data is dragging it away from the typical value.
 +
However, the median best retains this position and is not as strongly
 +
influenced by the skewed values. This is explained in more detail in
 +
the skewed distribution section later in this guide.
 +
 
 +
 +
== Median ==
 +
 +
The median is the middle score for a set of data
 +
that has been arranged in order of magnitude. The median is less
 +
affected by outliers and skewed data. In order to calculate the
 +
median, suppose we have the data below:
 +
 
 +
 +
 
 +
 
 +
 
 +
                         
 
{| border="1"
 
{| border="1"
 
|-
 
|-
 
|  
 
|  
'''Type of Variable'''
+
65
  
 
   
 
   
 
|  
 
|  
'''Best measure of central tendency'''
+
55
  
 
   
 
   
|-
 
 
|  
 
|  
Nominal
+
89
  
 
   
 
   
 
|  
 
|  
Mode
+
56
  
 
   
 
   
|-
 
 
|  
 
|  
Ordinal
+
35
  
 
   
 
   
 
|  
 
|  
Median
+
14
  
 
   
 
   
|-
 
 
|  
 
|  
Interval/Ratio (not skewed)
+
56
  
 
   
 
   
 
|  
 
|  
Mean
+
55
  
 
   
 
   
|-
 
 
|  
 
|  
Interval/Ratio (skewed)
+
87
  
 
   
 
   
 
|  
 
|  
Median
+
45
  
 
   
 
   
|}
+
|  
 +
92
  
== Relative advantages and disadvantages of mean, median and  mode ==
 
 
   
 
   
Mean.
+
|}
Advantages:
 
Finds the most accurate average of the set of numbers.
 
Disadvantages:
 
Outliers (few values are very different from most) can change the
 
mean a lot... making it much lower/higher than it should
 
be.
 
  
Median:
 
Advantages: Finds the middle number of a set of
 
data, so outliers have little or no effect.
 
Disadvantages: If the
 
gap between some numbers is large, while it is small between other
 
numbers in the data, this can cause the median to be a very
 
inaccurate way to find the middle of a set of
 
values.
 
  
Mode:
 
Advantages: Allows you to see what value
 
happened the most in a set of data. This can help you to figure out
 
things in a different way. It is also quick and easy.
 
Disadvantages:
 
Could be very far from the actual middle of the data. The least
 
reliable way to find the middle or average of the data.
 
  
 
   
 
   
 +
We first need to rearrange that data into order of
 +
magnitude (smallest first):
  
 +
  
 
This means that each of
 
these measures can be useful in different kinds of distributions.
 
  
 
  
 +
                         
 +
{| border="1"
 +
|-
 +
|
 +
14
  
 
   
 
   
== Activities ==
+
|
 +
35
 +
 
 
   
 
   
== Activity 1 : Central Tendency ==
+
|
 +
45
 +
 
 
   
 
   
==== Learning Objectives ====
+
|
 +
55
 +
 
 
   
 
   
Learn to calculate each average measure - Mean,
+
|
Median, Mode. And understand the difference between them. Know in
+
55
which situation which measure must be used.
 
  
 +
 +
|
 +
'''56'''
  
==== Pre-requisites/ Instructions ====
+
 
+
|
 +
56
  
 +
 +
|
 +
65
  
 
   
 
   
==== Materials and Resources Required ====
+
|
+
87
Paper and Pencil
 
  
 
   
 
   
==== Method ====
+
|
+
89
Solve the problems A and B
+
 
 
   
 
   
A. 27 members of a
 
class were given a puzzle to solve and the times (in minutes) each
 
pupil took to solve it were noted.
 
       
 
{| border="1"
 
|-
 
 
|  
 
|  
'''the times (in minutes) each pupil took'''
+
92
  
 
   
 
   
|-
+
|}
|
+
 
19 14 15 9 18 16 10 11 16
+
 
  
 
   
 
   
4 20 10 14 11 9 13 15 13
+
Our median mark is the middle mark - in this case
 +
56 (highlighted in bold). It is the middle mark because there are 5
 +
scores before it and 5 scores after it. This works fine when you have
 +
an odd number of scores but what happens when you have an even number
 +
of scores? What if you had only 10 scores? Well, you simply have to
 +
take the middle two scores and average the result. So, if we look at
 +
the example below:
  
 
   
 
   
12 2 17 15 14 10 11 10 12
+
 
 +
 
 +
 
 +
                       
 +
{| border="1"
 +
|-
 +
|
 +
65
  
 
   
 
   
|}
+
|  
 +
55
  
 
   
 
   
# The MEAN value of a set of data is Sum of Values / Number of Values . What is the mean (to 2 decimal places) of the times given in the table?
+
|
# The MEDIAN is the middle value of an ordered set of data.
+
89
## Write down the times in the table above in ascending order.
 
## How many values are there?
 
## What is the median ?
 
# The MODE is the value which occurs most often, i.e. the most popular.
 
## What is the mode of the times in the table above?
 
# Which of the three measures do you think is most representative of the average time? In this case it is probably the mean, but this will not always be so.
 
 
'''B Choosing which measure to use '''
 
 
The sales in one week of a particular dress are
 
given in terms of the dress sizes.
 
  
# Determine the mean, median and mode for this data .
 
# What is the size that is sold the most ?
 
# Which of these measures is of most use?
 
 
   
 
   
Dress sizes sold in one week
 
     
 
{| border="1"
 
|-
 
 
|  
 
|  
10
+
56
  
 
   
 
   
16
+
|
 +
35
  
 
   
 
   
16
+
|
 +
14
  
 
   
 
   
12
+
|
 +
56
  
 
   
 
   
16
+
|
 +
55
  
 
   
 
   
 
|  
 
|  
14
+
87
  
 
   
 
   
12
+
|
 +
45
  
 
   
 
   
14
+
|}
 +
 
 +
 
  
 
   
 
   
16
+
We again rearrange that data into order of
 +
magnitude (smallest first):
 +
 
  
 
18
 
  
+
                         
 +
{| border="1"
 +
|-
 
|  
 
|  
12
+
14
  
 
   
 
   
10
+
|
 +
35
  
 
   
 
   
18
+
|
 +
45
  
 
   
 
   
10
+
|
 +
55
  
 
   
 
   
14
+
|
 +
'''55'''
  
 
   
 
   
 
|  
 
|  
16
+
'''56'''
  
 
   
 
   
14
+
|
 +
56
  
 
   
 
   
8
+
|
 +
65
  
 
   
 
   
10
+
|
 +
87
  
 
   
 
   
16
+
|
 +
89
  
 
   
 
   
 
|  
 
|  
18
+
92
  
 
   
 
   
16
+
|}
  
 
14
 
  
 
16
 
  
 
   
 
   
8
+
Only now we have to take the 5th and 6th score in
 +
our data set and average them to get a median of 55.5.
  
 
   
 
   
|}
+
== Mode ==
 
   
 
   
==== Evaluation ====
+
The mode is the most frequent score in our data
 +
set. On a histogram it represents the highest bar in a bar chart or
 +
histogram. You can, therefore, sometimes consider the mode as being
 +
the most popular option. An example of a mode is presented below:
 +
 
 
   
 
   
# Does the student understand the difference between Mean, Median and Mode
 
# Can the student calculate each of the measures ?
 
# Does the student know which measure is useful and represents the actual data given a data set ?
 
  
== Self-Evaluation ==
+
 
 +
 
 
   
 
   
== Further Explorations ==
+
Normally, the mode is used for categorical data
 +
where we wish to know which is the most common category as
 +
illustrated below:
 +
 
 
   
 
   
== Enrichment Activities ==
+
We can see above that the most common form of
 +
transport, in this particular data set, is the bus. However, one of
 +
the problems with the mode is that it is not unique, so it leaves us
 +
with problems when we have two or more values that share the highest
 +
frequency, such as below:
 +
 
 
   
 
   
= Dispersion =
+
 
 +
 
 +
 
 
   
 
   
== Introduction ==
+
 
 +
 
 +
 
 
   
 
   
A measure of spread, sometimes also called a
+
 
measure of dispersion, is used to describe the variability in a
+
 
sample or population. It is usually used in conjunction with a
 
measure of central tendency, such as, the mean or median, to provide
 
an overall description of a set of data.
 
  
 
   
 
   
There are many reasons why the measure of the
+
 
spread of data values is important but one of the main reasons
+
 
regards its relationship with measures of central tendency. A measure
 
of spread gives us an idea of how well the mean, for example,
 
represents the data. If the spread of values in the data set is large
 
then the mean is not as representative of the data as if the spread
 
of data is small. This is because a large spread indicates that there
 
are probably large differences between individual scores.
 
Additionally, in research, it is often seen as positive if there is
 
little variation in each data group as it indicates that the similar.
 
  
 
   
 
   
We will be looking at the range, quartiles,
 
variance, absolute deviation and standard deviation.
 
  
== Objectives ==
+
 
 +
 
 
   
 
   
* Understand that a measure of dispersion is a measure of spread, is used to describe the variability in a sample or population.
+
 
* It is usually used in conjunction with a measure of central tendency, such as, the mean or median, to provide an overall description of a set of data.
+
 
* It important to measure the spread of data because we can understand its relationship with measures of central tendency to make more accurate interpretation of data.
+
 
* Understand and know the terms:Range, Quartile, Standard Deviation , Cumulative Frequency
 
* Calculation of Co-efficient of Variation. Meaning and interpretation of C.V. Analyse data and make conclusions
 
 
   
 
   
== Range ==
+
 
 +
 
 +
 
 
   
 
   
The range is the difference between the highest
 
and lowest scores in a data set and is the simplest measure of
 
spread. So we calculate range as:
 
  
Range = maximum value - minimum value
 
 
For example, let us consider the following data
 
set:
 
 
 
23 56 45 65 59 55 62 54 85 25
 
  
The maximum value is 85 and the minimum value is
 
23. This results in a range of 62, which is 85 minus 23. Whilst using
 
the range as a measure of spread is limited, it does set the
 
boundaries of the scores. This can be useful if you are measuring a
 
variable that has either a critical low or high threshold (or both)
 
that should not be crossed. The range will instantly inform you
 
whether at least one value broke these critical thresholds. In
 
addition, the range can be used to detect any errors when entering
 
data. For example, if you have recorded the age of school children in
 
your study and your range is 7 to 123 years old you know you have
 
made a mistake!
 
  
 
=== Quartiles and Interquartile Range ===
 
 
   
 
   
  
Quartiles tell us about the spread of a data set
 
by breaking the data set into quarters, just like the median breaks
 
it in half. For example, consider the marks of the 100 students
 
below, which have been ordered from the lowest to the highest scores,
 
and the quartiles highlighted in red.
 
  
 
Order Score Order Score Order Score Order
 
Score Order Score
 
  
 
   
 
   
1st 35 21st 42 41st 53 61st 64 81st 74
 
  
 
2nd 37 22nd 42 42nd 53 62nd 64 82nd 74
 
  
 
3rd 37 23rd 44 43rd 54 63rd 65 83rd 74
 
  
 
   
 
   
4th 38 24th 44 44th 55 64th 66 84th 75
+
We are now stuck as to which mode best describes
 
+
the central tendency of the data. This is particularly problematic
+
when we have continuous data, as we are more likely not to have any
5th 39 25th 45 45th 55 65th 67 85th 75
+
one value that is more frequent than the other. For example, consider
 +
measuring 30 peoples' weight (to the nearest 0.1 kg). How likely is
 +
it that we will find two or more people with '''exactly'''
 +
the same weight, e.g. 67.4 kg? The answer, is probably very unlikely
 +
- many people might be close but with such a small sample (30 people)
 +
and a large range of possible weights you are unlikely to find two
 +
people with exactly the same weight, that is, to the nearest 0.1 kg.
 +
This is why the mode is very rarely used with continuous data.
  
 
   
 
   
6th 39 26th 45 46th 56 66th 67 86th 76
+
 
 +
 
  
 
   
 
   
7th 39 27th 45 47th 57 67th 67 87th 77
+
Another problem with the mode is that it will not
 +
provide us with a very good measure of central tendency when the most
 +
common mark is far away from the rest of the data in the data set, as
 +
depicted in the diagram below:
  
 
   
 
   
8th 39 28th 45 48th 57 68th 67 88th 77
 
  
+
 
9th 39 29th 47 49th 58 69th 68 89th 79
 
  
 
   
 
   
10th 40 30th 48 50th 58 70th 69 90th 80
 
  
 
11th 40 31st 49 51st 59 71st 69 91st 81
 
  
 
12th 40 32nd 49 52nd 60 72nd 69 92nd 81
 
  
 
   
 
   
13th 40 33rd 49 53rd 61 73rd 70 93rd 81
 
  
 
14th 40 34th 49 54th 62 74th 70 94th 81
 
  
 
15th 40 35th 51 55th 62 75th 71 95th 81
 
  
 
   
 
   
16th 41 36th 51 56th 62 76th 71 96th 81
 
  
 
17th 41 37th 51 57th 63 77th 71 97th 83
 
  
 
18th 42 38th 51 58th 63 78th 72 98th 84
 
  
 
   
 
   
19th 42 39th 52 59th 64 79th 74 99th 84
 
  
+
 
20th 42 40th 52 60th 64 80th 74 100th 85
 
  
 
   
 
   
The first quartile (Q1) lies between the 25th and
 
26th student's marks, the second quartile (Q2) between the 50th and
 
51st student's marks, and the third quartile (Q3) between the 75th
 
and 76th student's marks. Hence:
 
  
First quartile (Q1) = 45 + 45 ÷ 2 = 45
+
 
  
 
   
 
   
Second quartile (Q2) = 58 + 59 ÷ 2 = 58.5
+
 
 +
 
  
 
   
 
   
Third quartile (Q3) = 71 + 71 ÷ 2 = 71
 
  
In the above example, we have an even number of
 
scores (100 students rather than an odd number such as 99 students).
 
This means that when we calculate the quartiles, we take the sum of
 
the two scores around each quartile and then half them (hence Q1= 45
 
+ 45 ÷ 2 = 45) . However, if we had an odd number of scores (say, 99
 
students), then we would only need to take one score for each
 
quartile (that is, the 25th, 50th and 75th scores). You should
 
recognize that the second quartile is also the median.
 
  
Quartiles are a useful measure of spread because
 
they are much less affected by outliers or a skewed data set than the
 
equivalent measures of mean and standard deviation. For this reason,
 
quartiles are often reported along with the median as the best choice
 
of measure of spread and central tendency, respectively, when dealing
 
with skewed and/or data with outliers. A common way of expressing
 
quartiles is as an interquartile range. The interquartile range
 
describes the difference between the third quartile (Q3) and the
 
first quartile (Q1), telling us about the range of the middle half of
 
the scores in the distribution. Hence, for our 100 students:
 
  
Interquartile range = Q3 - Q1
+
 +
 
 +
 
  
 
   
 
   
= 71 - 45
+
 
 +
 
  
 
   
 
   
= 26
 
  
However, it should be noted that in journals and
 
other publications you will usually see the interquartile range
 
reported as 45 to 71, rather than the calculated range.
 
  
A slight variation on this is the
 
semi-interquartile range, which is half the interquartile range = ½
 
(Q3 - Q1). Hence, for our 100 students, this would be 26 ÷ 2 = 13.
 
  
== Standard Deviation ==
 
 
   
 
   
The standard deviation is a measure of the spread
+
 
of scores within a set of data. Usually, we are interested in the
+
 
standard deviation of a population. However, as we are often
 
presented with data from a sample only, we can estimate the
 
population standard deviation from a sample standard deviation. These
 
two standard deviations, sample and population standard deviations,
 
are calculated differently. In statistics we are usually presented
 
with having to calculate sample standard deviations, and so this is
 
what this article will focus on, although the formula for a
 
population standard deviation will also be shown.
 
  
 
   
 
   
=== When to use the sample or population standard deviation ===
+
 
 +
 
 +
 
 
   
 
   
We are normally interested in knowing the
+
 
population standard deviation as our population contains all the
+
 
values we are interested in. Therefore, you would normally calculate
 
the population standard deviation if: (1) you have the entire
 
population or (2) you have a sample of a larger population but you
 
are only interested in this sample and do not wish to generalize your
 
findings to the population. However, in statistics, we are usually
 
presented with a sample from which we wish to estimate (generalize
 
to) a population, and the standard deviation is no exception to this.
 
Therefore, if all you have is a sample but you wish to make a
 
statement about the population standard deviation from which the
 
sample is drawn, then you need to use the sample standard deviation.
 
Confusion can often arise as to which standard deviation to use due
 
to the name &quot;sample&quot; standard deviation incorrectly being
 
interpreted as meaning the standard deviation of the sample itself
 
and not as the estimate of the population standard deviation based on
 
the sample.
 
  
 
   
 
   
=== What type of data should you use when you calculate a standard deviation? ===
+
 
+
 
The standard deviation is used in conjunction with
 
the mean, to summarise [[continuous]]
 
data not categorical data. In addition, the standard deviation, like
 
the [[mean]],
 
is normally only appropriate when the continuous data is not
 
significantly skewed or has outliers.
 
  
 
   
 
   
=== Examples of when to use the sample or population standard deviation ===
+
 
 +
 
 +
 
 
   
 
   
Q. A teacher sets an exam for their pupils. The
+
 
teacher wants to summarize the results the pupils attained as a mean
+
 
and standard deviation. Which standard deviation should be used?
 
  
 
   
 
   
A. Population standard deviation. Why? Because the
+
 
teacher is only interested in this class of pupils' scores and nobody
+
 
else.
 
  
 
   
 
   
Q. A researcher has recruited males aged 45 to 65
+
 
years old for an exercise training study to investigate risk markers
+
 
for heart disease, e.g. cholesterol. Which standard deviation would
 
most likely be used?
 
  
 
   
 
   
A. Sample standard deviation. Although not
+
 
explicitly stated, a researcher investigating health related issues
+
 
will not be simply concerned with just the participants of their
 
study; they will want to show how their sample results can be
 
generalised to the whole population (in this case, males aged 45 to
 
65 years old). Hence, the use of the sample standard deviation.
 
  
 
   
 
   
Q. One of the questions on a national consensus
+
In the above diagram the mode has a value of 2. We
survey asks for respondent's age. Which standard deviation would be
+
can clearly see, however, that the mode is not representative of the
used to describe the variation in all ages received from the
+
data, which is mostly concentrated around the 20 to 30 value range.
consensus?
+
To use the mode to describe the central tendency of this data set
 +
would be misleading.
  
 
   
 
   
A. Population standard deviation. A national
+
== Skewed Distributions and the Mean and Median ==
consensus is used to find out information about the nation's
+
citizens. By definition, it includes the whole population, therefore,
+
We often test whether our data is normally
a population standard deviation would be used.
+
distributed as this is a common assumption underlying many
 +
statistical tests. An example of a normally distributed set of data
 +
is presented below:
  
 
   
 
   
=== What are the formulas for the standard deviation? ===
+
 
 +
 
 +
 
 
   
 
   
The '''sample standard deviation formula'''
+
When you have a normally distributed sample you
is:
+
can legitimately use both the mean or the median as your measure of
 +
central tendency. In fact, in any symmetrical distribution the mean,
 +
median and mode are equal. However, in this situation, the mean is
 +
widely preferred as the best measure of central tendency as it is the
 +
measure that includes all the values in the data set for its
 +
calculation, and any change in any of the scores will affect the
 +
value of the mean. This is not the case with the median or mode.
  
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_m5610ded5.gif]]
+
However, when our data is skewed, for example, as
 +
with the right-skewed data set below:
  
 
   
 
   
where,
+
 
 +
 
  
 
   
 
   
s = sample standard
+
 
deviation
+
 
Σ = sum
 
of...
 
X = sample mean
 
n = number of scores in sample.
 
  
 
   
 
   
The '''population standard deviation'''
+
 
formula is:
+
 
  
 
   
 
   
[[File:KOER-%20Mathematics%20-%20Statistics_html_m48922b88.gif]]
+
 
 +
 
  
 
   
 
   
where,
+
 
 +
 
  
 
   
 
   
σ
 
= population standard deviation
 
Σ
 
= sum of...
 
μ =
 
population mean
 
n = number of scores in sample.
 
  
 
+
 
== Variation ==
+
 
 
   
 
   
Quartiles are useful but they are also somewhat
 
limited because they do not take into account every score in our
 
group of data. To get a more representative idea of spread we need to
 
take into account the actual values of each score in a data set. The
 
absolute deviation, variance and standard deviation are such
 
measures.
 
  
The absolute and mean absolute deviation show the
+
 
amount of deviation (variation) that occurs around the mean score. To
 
find the total variability in our group of data, we simply add up the
 
deviation of each score from the mean. The average deviation of a
 
score can then be calculated by dividing this total by the number of
 
scores. How we calculate the deviation of a score from the mean
 
depends on our choice of statistic, whether we use absolute
 
deviation, variance or standard deviation.
 
  
 
   
 
   
=== Absolute Deviation and Mean Absolute Deviation ===
+
 
 +
 
 +
 
 +
 +
 
 +
 
 +
 
 
   
 
   
Perhaps the simplest way of calculating the
 
deviation of a score from the mean is to take each score and minus
 
the mean score. For example, the mean score for the group of 100
 
students we used earlier was 58.75 out of 100. Therefore, if we took
 
a student that scored 60 out of 100, the deviation of a score from
 
the mean is 60 - 58.75 = 1.25. It is important to note that scores
 
above the mean have positive deviations (as demonstrated above)
 
whilst that scores below the mean will have negative deviations.
 
  
To find out the total variability in our data set,
+
 
we would perform this calculation for all of the 100 students'
+
 
scores. However, the problem is that because we have both positive
 
and minus signs, when we add up all of these deviations, they cancel
 
each other out, giving us a total deviation of zero. Since we are
 
only interested in the deviations of the scores and not whether they
 
are above or below the mean score, we can ignore the minus sign and
 
take only the absolute value, giving us the absolute deviation.
 
Adding up all of these absolute deviations and dividing them by the
 
total number of scores then gives us the mean absolute deviation (see
 
below). Therefore, for our 100 students the mean absolute deviation
 
is 12.81, as shown below:
 
 
   
 
   
=== Variance ===
+
 
 +
 
 +
 
 
   
 
   
Another method for calculating the deviation of a
 
group of scores from the mean, such as the 100 students we used
 
earlier, is to use the variance. Unlike the absolute deviation, which
 
uses the absolute value of the deviation in order to &quot;rid
 
itself&quot; of the negative values, the variance achieves positive
 
values by squaring each of the deviations instead. Adding up these
 
squared deviations gives us the sum of squares, which we can then
 
divide by the total number of scores in our group of data (in other
 
words, 100 because there are 100 students) to find the variance (see
 
below). Therefore, for our 100 students, the variance is 211.89, as
 
shown below:
 
  
As a measure of variability, the variance is
 
useful. If the scores in our group of data are spread out then the
 
variance will be a large number. Conversely, if the scores are spread
 
closely around the mean, then the variance will be a smaller number.
 
However, there are two potential problems with the variance. First,
 
because the deviations of scores from the mean are 'squared', this
 
gives more weight to extreme scores. If our data contains outliers
 
(in other words, one or a small number of scores that are
 
particularly far away from the mean and perhaps do not represent well
 
our data as a whole) this can give undo weight to these scores.
 
Secondly, the variance is not in the same units as the scores in our
 
data set: variance is measured in the units squared. This means we
 
cannot place it on our frequency distribution and cannot directly
 
relate its value to the values in our data set. Therefore, the figure
 
of 211.89, our variance, appears somewhat arbitrary. Calculating the
 
standard deviation rather than the variance rectifies this problem.
 
Nonetheless, analysing variance is extremely important in some
 
statistical analyses, discussed in other statistical guides.
 
  
== Coefficient of variation ===
+
 
 
   
 
   
Coefficient of variation is defined as
 
  
 
[[File:KOER-%20Mathematics%20-%20Statistics_html_1afc44b3.png]]
 
 
where v is the standard
 
deviation and x is the mean of the given data. It is also called as
 
  
 
a relative standard
 
deviation.
 
  
 
   
 
   
'''Remarks '''
 
  
 
* The coefficient of variation helps us to compare the consistency of two or more
 
* collections of data.
 
* When the coefficient of variation is more, the given data is less consistent.
 
* When the coefficient of variation is less, the given data is more consistent.
 
  
== Self-Evaluation ==
 
 
== Further Explorations ==
 
 
== Enrichment Activities ==
 
 
= Additional Resources =
 
 
== Books ==
 
 
&quot;How to lie with statistics&quot; by Darrell
 
Huff, Pelican, ISBN 0 14 021300 7
 
  
 
   
 
   
&quot;Use and abuse of statistics&quot; by W.
 
Reichmann, Pelican , ISBN 0 14 020707 4
 
  
 
&quot;Figuring and society&quot; by Ronald Meek,
 
Fontana ISBN 0 00 632560
 
  
 
'''Websites'''
 
  
 
   
 
   
[http://en.wikipedia.org/wiki/Statistics http://en.wikipedia.org/wiki/Statistics]
+
 
 +
 
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
 
 +
 
  
 
   
 
   
[http://www.gnu.org/software/pspp/ http://www.gnu.org/software/pspp/]
+
 
 +
 
 +
 
 +
 +
we find that the mean is being dragged in the
 +
direct of the skew. In these situations, the median is generally
 +
considered to be the best representative of the central location of
 +
the data. The more skewed the distribution the greater the difference
 +
between the median and mean, and the greater emphasis should be
 +
placed on using the median as opposed to the mean. A classic example
 +
of the above right-skewed distribution is income (salary), where
 +
higher-earners provide a false representation of the typical income
 +
if expressed as a mean and not a median.
 +
 
 +
 +
If dealing with a normal distribution, and tests
 +
of normality show that the data is non-normal, then it is customary
 +
to use the median instead of the mean. This is more a rule of thumb
 +
than a strict guideline however. Sometimes, researchers wish to
 +
report the mean of a skewed distribution if the median and mean are
 +
not appreciably different (a subjective assessment) and if it allows
 +
easier comparisons to previous research to be made.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
== Summary of when to use the mean, median and mode ==
 +
 +
Please use the following summary table to know
 +
what the best measure of central tendency is with respect to the
 +
different types of variables.
 +
 
 +
 +
 
 +
 
 +
 
 +
                       
 +
{| border="1"
 +
|-
 +
|
 +
'''Type of Variable'''
 +
 
 +
 +
|
 +
'''Best measure of central tendency'''
 +
 
 +
 +
|-
 +
|
 +
Nominal
 +
 
 +
 +
|
 +
Mode
 +
 
 +
 +
|-
 +
|
 +
Ordinal
 +
 
 +
 +
|
 +
Median
 +
 
 +
 +
|-
 +
|
 +
Interval/Ratio (not skewed)
 +
 
 +
 +
|
 +
Mean
 +
 
 +
 +
|-
 +
|
 +
Interval/Ratio (skewed)
 +
 
 +
 +
|
 +
Median
 +
 
 +
 +
|}
 +
 
 +
 
 +
 
 +
 +
== Relative advantages and disadvantages of mean, median and  mode ==
 +
 +
Mean.
 +
Advantages:
 +
Finds the most accurate average of the set of numbers.
 +
Disadvantages:
 +
Outliers (few values are very different from most) can change the
 +
mean a lot... making it much lower/higher than it should
 +
be.
 +
 
 +
Median:
 +
Advantages: Finds the middle number of a set of
 +
data, so outliers have little or no effect.
 +
Disadvantages: If the
 +
gap between some numbers is large, while it is small between other
 +
numbers in the data, this can cause the median to be a very
 +
inaccurate way to find the middle of a set of
 +
values.
 +
 
 +
Mode:
 +
Advantages: Allows you to see what value
 +
happened the most in a set of data. This can help you to figure out
 +
things in a different way. It is also quick and easy.
 +
Disadvantages:
 +
Could be very far from the actual middle of the data. The least
 +
reliable way to find the middle or average of the data.
 +
 
 +
 +
 
 +
 
 +
 +
This means that each of
 +
these measures can be useful in different kinds of distributions.
 +
 
 +
 +
 
 +
 
 +
 +
= Dispersion =
 +
 +
A measure of spread, sometimes also called a
 +
measure of dispersion, is used to describe the variability in a
 +
sample or population. It is usually used in conjunction with a
 +
measure of central tendency, such as, the mean or median, to provide
 +
an overall description of a set of data.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
=== Why is it important to measure the spread of data? ===
 +
 +
There are many reasons why the measure of the
 +
spread of data values is important but one of the main reasons
 +
regards its relationship with measures of central tendency. A measure
 +
of spread gives us an idea of how well the mean, for example,
 +
represents the data. If the spread of values in the data set is large
 +
then the mean is not as representative of the data as if the spread
 +
of data is small. This is because a large spread indicates that there
 +
are probably large differences between individual scores.
 +
Additionally, in research, it is often seen as positive if there is
 +
little variation in each data group as it indicates that the similar.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
We will be looking at the range, quartiles,
 +
variance, absolute deviation and standard deviation.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
=== Range ===
 +
 +
 
 +
 
 +
 
 +
 +
The range is the difference between the highest
 +
and lowest scores in a data set and is the simplest measure of
 +
spread. So we calculate range as:
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
Range = maximum value - minimum value
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
For example, let us consider the following data
 +
set:
 +
 
 +
 +
23 56 45 65 59 55 62 54 85 25
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
The maximum value is 85 and the minimum value is
 +
23. This results in a range of 62, which is 85 minus 23. Whilst using
 +
the range as a measure of spread is limited, it does set the
 +
boundaries of the scores. This can be useful if you are measuring a
 +
variable that has either a critical low or high threshold (or both)
 +
that should not be crossed. The range will instantly inform you
 +
whether at least one value broke these critical thresholds. In
 +
addition, the range can be used to detect any errors when entering
 +
data. For example, if you have recorded the age of school children in
 +
your study and your range is 7 to 123 years old you know you have
 +
made a mistake!
 +
 
 +
 
 +
 
 +
 +
=== Quartiles and Interquartile Range ===
 +
 +
 
 +
 
 +
 
 +
 +
Quartiles tell us about the spread of a data set
 +
by breaking the data set into quarters, just like the median breaks
 +
it in half. For example, consider the marks of the 100 students
 +
below, which have been ordered from the lowest to the highest scores,
 +
and the quartiles highlighted in red.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
Order Score Order Score Order Score Order
 +
Score Order Score
 +
 
 +
 +
1st 35 21st 42 41st 53 61st 64 81st 74
 +
 
 +
 +
2nd 37 22nd 42 42nd 53 62nd 64 82nd 74
 +
 
 +
 +
3rd 37 23rd 44 43rd 54 63rd 65 83rd 74
 +
 
 +
 +
4th 38 24th 44 44th 55 64th 66 84th 75
 +
 
 +
 +
5th 39 25th 45 45th 55 65th 67 85th 75
 +
 
 +
 +
6th 39 26th 45 46th 56 66th 67 86th 76
 +
 
 +
 +
7th 39 27th 45 47th 57 67th 67 87th 77
 +
 
 +
 +
8th 39 28th 45 48th 57 68th 67 88th 77
 +
 
 +
 +
9th 39 29th 47 49th 58 69th 68 89th 79
 +
 
 +
 +
10th 40 30th 48 50th 58 70th 69 90th 80
 +
 
 +
 +
11th 40 31st 49 51st 59 71st 69 91st 81
 +
 
 +
 +
12th 40 32nd 49 52nd 60 72nd 69 92nd 81
 +
 
 +
 +
13th 40 33rd 49 53rd 61 73rd 70 93rd 81
 +
 
 +
 +
14th 40 34th 49 54th 62 74th 70 94th 81
 +
 
 +
 +
15th 40 35th 51 55th 62 75th 71 95th 81
 +
 
 +
 +
16th 41 36th 51 56th 62 76th 71 96th 81
 +
 
 +
 +
17th 41 37th 51 57th 63 77th 71 97th 83
 +
 
 +
 +
18th 42 38th 51 58th 63 78th 72 98th 84
 +
 
 +
 +
19th 42 39th 52 59th 64 79th 74 99th 84
 +
 
 +
 +
20th 42 40th 52 60th 64 80th 74 100th 85
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
The first quartile (Q1) lies between the 25th and
 +
26th student's marks, the second quartile (Q2) between the 50th and
 +
51st student's marks, and the third quartile (Q3) between the 75th
 +
and 76th student's marks. Hence:
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
First quartile (Q1) = 45 + 45 ÷ 2 = 45
 +
 
 +
 +
Second quartile (Q2) = 58 + 59 ÷ 2 = 58.5
 +
 
 +
 +
Third quartile (Q3) = 71 + 71 ÷ 2 = 71
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
In the above example, we have an even number of
 +
scores (100 students rather than an odd number such as 99 students).
 +
This means that when we calculate the quartiles, we take the sum of
 +
the two scores around each quartile and then half them (hence Q1= 45
 +
+ 45 ÷ 2 = 45) . However, if we had an odd number of scores (say, 99
 +
students), then we would only need to take one score for each
 +
quartile (that is, the 25th, 50th and 75th scores). You should
 +
recognize that the second quartile is also the median.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
Quartiles are a useful measure of spread because
 +
they are much less affected by outliers or a skewed data set than the
 +
equivalent measures of mean and standard deviation. For this reason,
 +
quartiles are often reported along with the median as the best choice
 +
of measure of spread and central tendency, respectively, when dealing
 +
with skewed and/or data with outliers. A common way of expressing
 +
quartiles is as an interquartile range. The interquartile range
 +
describes the difference between the third quartile (Q3) and the
 +
first quartile (Q1), telling us about the range of the middle half of
 +
the scores in the distribution. Hence, for our 100 students:
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
Interquartile range = Q3 - Q1
 +
 
 +
 +
= 71 - 45
 +
 
 +
 +
= 26
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
However, it should be noted that in journals and
 +
other publications you will usually see the interquartile range
 +
reported as 45 to 71, rather than the calculated range.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
A slight variation on this is the
 +
semi-interquartile range, which is half the interquartile range = ½
 +
(Q3 - Q1). Hence, for our 100 students, this would be 26 ÷ 2 = 13.
 +
 
 +
 +
== Standard Deviation ==
 +
 +
=== Introduction ===
 +
 +
The standard deviation is a measure of the spread
 +
of scores within a set of data. Usually, we are interested in the
 +
standard deviation of a population. However, as we are often
 +
presented with data from a sample only, we can estimate the
 +
population standard deviation from a sample standard deviation. These
 +
two standard deviations, sample and population standard deviations,
 +
are calculated differently. In statistics we are usually presented
 +
with having to calculate sample standard deviations, and so this is
 +
what this article will focus on, although the formula for a
 +
population standard deviation will also be shown.
 +
 
 +
 +
=== When to use the sample or population standard deviation ===
 +
 +
We are normally interested in knowing the
 +
population standard deviation as our population contains all the
 +
values we are interested in. Therefore, you would normally calculate
 +
the population standard deviation if: (1) you have the entire
 +
population or (2) you have a sample of a larger population but you
 +
are only interested in this sample and do not wish to generalize your
 +
findings to the population. However, in statistics, we are usually
 +
presented with a sample from which we wish to estimate (generalize
 +
to) a population, and the standard deviation is no exception to this.
 +
Therefore, if all you have is a sample but you wish to make a
 +
statement about the population standard deviation from which the
 +
sample is drawn, then you need to use the sample standard deviation.
 +
Confusion can often arise as to which standard deviation to use due
 +
to the name &quot;sample&quot; standard deviation incorrectly being
 +
interpreted as meaning the standard deviation of the sample itself
 +
and not as the estimate of the population standard deviation based on
 +
the sample.
 +
 
 +
 +
=== What type of data should you use when you calculate a standard deviation? ===
 +
 +
The standard deviation is used in conjunction with
 +
the mean, to summarise [[continuous]]
 +
data not categorical data. In addition, the standard deviation, like
 +
the [[mean]],
 +
is normally only appropriate when the continuous data is not
 +
significantly skewed or has outliers.
 +
 
 +
 +
=== Examples of when to use the sample or population standard deviation ===
 +
 +
Q. A teacher sets an exam for their pupils. The
 +
teacher wants to summarize the results the pupils attained as a mean
 +
and standard deviation. Which standard deviation should be used?
 +
 
 +
 +
A. Population standard deviation. Why? Because the
 +
teacher is only interested in this class of pupils' scores and nobody
 +
else.
 +
 
 +
 +
Q. A researcher has recruited males aged 45 to 65
 +
years old for an exercise training study to investigate risk markers
 +
for heart disease, e.g. cholesterol. Which standard deviation would
 +
most likely be used?
 +
 
 +
 +
A. Sample standard deviation. Although not
 +
explicitly stated, a researcher investigating health related issues
 +
will not be simply concerned with just the participants of their
 +
study; they will want to show how their sample results can be
 +
generalised to the whole population (in this case, males aged 45 to
 +
65 years old). Hence, the use of the sample standard deviation.
 +
 
 +
 +
Q. One of the questions on a national consensus
 +
survey asks for respondent's age. Which standard deviation would be
 +
used to describe the variation in all ages received from the
 +
consensus?
 +
 
 +
 +
A. Population standard deviation. A national
 +
consensus is used to find out information about the nation's
 +
citizens. By definition, it includes the whole population, therefore,
 +
a population standard deviation would be used.
 +
 
 +
 +
=== What are the formulas for the standard deviation? ===
 +
 +
The '''sample standard deviation formula'''
 +
is:
 +
 
 +
 +
[[Image:Statistics_html_m5610ded5.gif]]
 +
 
 +
 +
where,
 +
 
 +
 +
s = sample standard
 +
deviation
 +
Σ = sum
 +
of...
 +
X = sample mean
 +
n = number of scores in sample.
 +
 
 +
 +
The '''population standard deviation'''
 +
formula is:
 +
 
 +
 +
[[Image:Statistics_html_m48922b88.gif]]
 +
 
 +
 +
where,
 +
 
 +
 +
σ
 +
= population standard deviation
 +
Σ
 +
= sum of...
 +
μ =
 +
population mean
 +
n = number of scores in sample.
 +
 
 +
 
 +
== Variation ==
 +
 +
 
 +
 
 +
 
 +
 +
Quartiles are useful but they are also somewhat
 +
limited because they do not take into account every score in our
 +
group of data. To get a more representative idea of spread we need to
 +
take into account the actual values of each score in a data set. The
 +
absolute deviation, variance and standard deviation are such
 +
measures.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
The absolute and mean absolute deviation show the
 +
amount of deviation (variation) that occurs around the mean score. To
 +
find the total variability in our group of data, we simply add up the
 +
deviation of each score from the mean. The average deviation of a
 +
score can then be calculated by dividing this total by the number of
 +
scores. How we calculate the deviation of a score from the mean
 +
depends on our choice of statistic, whether we use absolute
 +
deviation, variance or standard deviation.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
=== Absolute Deviation and Mean Absolute Deviation ===
 +
 +
 
 +
 
 +
 
 +
 +
Perhaps the simplest way of calculating the
 +
deviation of a score from the mean is to take each score and minus
 +
the mean score. For example, the mean score for the group of 100
 +
students we used earlier was 58.75 out of 100. Therefore, if we took
 +
a student that scored 60 out of 100, the deviation of a score from
 +
the mean is 60 - 58.75 = 1.25. It is important to note that scores
 +
above the mean have positive deviations (as demonstrated above)
 +
whilst that scores below the mean will have negative deviations.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
To find out the total variability in our data set,
 +
we would perform this calculation for all of the 100 students'
 +
scores. However, the problem is that because we have both positive
 +
and minus signs, when we add up all of these deviations, they cancel
 +
each other out, giving us a total deviation of zero. Since we are
 +
only interested in the deviations of the scores and not whether they
 +
are above or below the mean score, we can ignore the minus sign and
 +
take only the absolute value, giving us the absolute deviation.
 +
Adding up all of these absolute deviations and dividing them by the
 +
total number of scores then gives us the mean absolute deviation (see
 +
below). Therefore, for our 100 students the mean absolute deviation
 +
is 12.81, as shown below:
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
=== Variance ===
 +
 +
 
 +
 
 +
 
 +
 +
Another method for calculating the deviation of a
 +
group of scores from the mean, such as the 100 students we used
 +
earlier, is to use the variance. Unlike the absolute deviation, which
 +
uses the absolute value of the deviation in order to &quot;rid
 +
itself&quot; of the negative values, the variance achieves positive
 +
values by squaring each of the deviations instead. Adding up these
 +
squared deviations gives us the sum of squares, which we can then
 +
divide by the total number of scores in our group of data (in other
 +
words, 100 because there are 100 students) to find the variance (see
 +
below). Therefore, for our 100 students, the variance is 211.89, as
 +
shown below:
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
As a measure of variability, the variance is
 +
useful. If the scores in our group of data are spread out then the
 +
variance will be a large number. Conversely, if the scores are spread
 +
closely around the mean, then the variance will be a smaller number.
 +
However, there are two potential problems with the variance. First,
 +
because the deviations of scores from the mean are 'squared', this
 +
gives more weight to extreme scores. If our data contains outliers
 +
(in other words, one or a small number of scores that are
 +
particularly far away from the mean and perhaps do not represent well
 +
our data as a whole) this can give undo weight to these scores.
 +
Secondly, the variance is not in the same units as the scores in our
 +
data set: variance is measured in the units squared. This means we
 +
cannot place it on our frequency distribution and cannot directly
 +
relate its value to the values in our data set. Therefore, the figure
 +
of 211.89, our variance, appears somewhat arbitrary. Calculating the
 +
standard deviation rather than the variance rectifies this problem.
 +
Nonetheless, analysing variance is extremely important in some
 +
statistical analyses, discussed in other statistical guides.
 +
 
 +
 +
 
 +
 
 +
 +
=== Coefficient of variation ===
 +
 +
Coefficient of
 +
variation is defined as
 +
 
 +
 +
[[Image:Statistics_html_1afc44b3.png]]
 +
 
 +
 +
 
 +
 
 +
 +
 
 +
 
 +
 +
where v is the standard
 +
deviation and x is the mean of the given data. It is also called as
 +
 
 +
 +
a relative standard
 +
deviation.
 +
 
 +
 +
Remarks
 +
 
 +
 +
(i) The coefficient of
 +
variation helps us to compare the consistency of two or more
 +
 
 +
 +
collections of data.
 +
 
 +
 +
(ii) When the
 +
coefficient of variation is more, the given data is less consistent.
 +
 
 +
 +
(iii) When the
 +
coefficient of variation is less, the given data is more consistent.
 +
 
 +
 +
 
 +
 
 +
 +
== Key Vocabulary ==
 +
 +
 
 +
 
 +
 
 +
 +
== Additional Resources: ==
 +
 +
[[http://en.wikipedia.org/wiki/Statistics]]
 +
 
 +
 +
[[http://www.gnu.org/software/pspp/]]
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
= Activities : =
 +
 +
== Activity 1 : Data Collection ==
 +
 +
=== Objective ===
 +
 +
Understand collection of data and preparing
 +
frequency distrubution table for a given sets of sources
 +
 
 +
 +
=== Procedure ===
 +
 +
Collect information
 +
regarding the number of family members of your classmates and
 +
represent it in the form of a table. Find to which category most
 +
students belong.
 +
 
 +
 +
 
 +
 
 +
 +
 
 +
 
 +
 +
 
 +
 
 +
             
 +
{| border="1"
 +
|-
 +
|
 +
Number of family members
 +
 
 +
 +
|
 +
Tally marks members
 +
 
 +
 +
|
 +
Number of students
 +
 
 +
 +
with that many
 +
 
 +
 +
family members
 +
 
 +
 +
|-
 +
|
 +
 
 +
 
 +
 +
|
 +
 
 +
 
 +
 +
|
 +
 
 +
 
 +
 +
|}
 +
 
 +
 
 +
 +
Make a table and enter
 +
the data using tally marks. Find the number that appeared
 +
 
 +
 +
 
 +
 
 +
 +
(a) the minimum number
 +
of times?
 +
 
 +
 +
 
 +
 
 +
 +
(b) the maximum number
 +
of times?
 +
 
 +
 +
 
 +
 
 +
 +
(c) same number of
 +
times?
 +
 
 +
 +
 
 +
 
 +
 +
 
 +
 
 +
 +
== Avtivity 2: Histogram and Bar Chart ==
 +
 +
=== Objective ===
 +
 +
Learn to draw a histogram and bar chart.
 +
Understand the difference between a bar chart and a hsitogram and be
 +
able to select the approriate chart by looking at the problem and
 +
data.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
=== Materials ===
 +
 +
Paper and Pencil
 +
 
 +
 +
=== Procedure ===
 +
 +
Solve the problems A and B
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
In the past year, you have recorded the number of
 +
tickets that a movie theater has sold during each month. To
 +
represent this data set graphically, would you construct a bar graph
 +
or a histogram? Why is this choice better than the other? Using the
 +
following data, construct the graph that you choose.
 +
 
 +
                                                       
 +
{| border="1"
 +
|-
 +
|
 +
Month
 +
 
 +
 +
|
 +
Number of Tickets Sold
 +
 
 +
 +
|-
 +
|
 +
January
 +
 
 +
 +
|
 +
25
 +
 
 +
 +
|-
 +
|
 +
February
 +
 
 +
 +
|
 +
20
 +
 
 +
 +
|-
 +
|
 +
March
 +
 
 +
 +
|
 +
15
 +
 
 +
 +
|-
 +
|
 +
April
 +
 
 +
 +
|
 +
20
 +
 
 +
 +
|-
 +
|
 +
May
 +
 
 +
 +
|
 +
30
 +
 
 +
 +
|-
 +
|
 +
June
 +
 
 +
 +
|
 +
35
 +
 
 +
 +
|-
 +
|
 +
July
 +
 
 +
 +
|
 +
40
 +
 
 +
 +
|-
 +
|
 +
August
 +
 
 +
 +
|
 +
20
 +
 
 +
 +
|-
 +
|
 +
September
 +
 
 +
 +
|
 +
25
 +
 
 +
 +
|-
 +
|
 +
October
 +
 
 +
 +
|
 +
15
 +
 
 +
 +
|-
 +
|
 +
November
 +
 
 +
 +
|
 +
20
 +
 
 +
 +
|-
 +
|
 +
December
 +
 
 +
 +
|
 +
30
 +
 
 +
 +
|}
 +
 
 +
 
 +
 +
 
 +
 
 +
 +
B For a recent science
 +
project, you collected data regarding the distribution of fish and
 +
aquatic life in a nearby pond. Your data consists of the number of
 +
living creatures found in each 1 meter depth increment in the pond.
 +
Construct a bar graph and several histograms (vary the depth
 +
increment size) for the following data. In which case(s) is the
 +
histogram the same as the bar graph? How do the other histograms vary
 +
from the bar graph?
 +
 
 +
 +
 
 +
 
 +
                                               
 +
{| border="1"
 +
|-
 +
|
 +
'''Depth Range'''
 +
 
 +
 +
|
 +
'''Number of Living Creatures '''
 +
 
 +
 +
|-
 +
|
 +
0 – 1 meters
 +
 
 +
 +
|
 +
10
 +
 
 +
 +
|-
 +
|
 +
1 – 2 meters
 +
 
 +
 +
|
 +
93
 +
 
 +
 +
|-
 +
|
 +
2 – 3 meters
 +
 
 +
 +
|
 +
23
 +
 
 +
 +
|-
 +
|
 +
3 – 4 meters
 +
 
 +
 +
|
 +
47
 +
 
 +
 +
|-
 +
|
 +
4 – 5 meters
 +
 
 +
 +
|
 +
68
 +
 
 +
 +
|-
 +
|
 +
5 – 6 meters
 +
 
 +
 +
|
 +
51
 +
 
 +
 +
|-
 +
|
 +
6 – 7 meters
 +
 
 +
 +
|
 +
43
 +
 
 +
 +
|-
 +
|
 +
7 – 8 meters
 +
 
 +
 +
|
 +
21
 +
 
 +
 +
|-
 +
|
 +
8 – 9 meters
 +
 
 +
 +
|
 +
15
 +
 
 +
 +
|-
 +
|
 +
9 – 10 meters
 +
 
 +
 +
|
 +
8
 +
 
 +
 +
|}
 +
== Evaluation ==
 +
 +
# Does the student understand the difference between a bar chart and a histogram ?
 +
# Does the student know when to use each of these charts - - depending on the type of data continous and discrete ?
 +
 +
== Activity 3 : Central Tendency ==
 +
 +
=== Objective ===
 +
 +
Learn to calculate each average measure - Mean,
 +
Median, Mode. And understand the difference between them. Know in
 +
which situation which measure must be used.
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
=== Materials ===
 +
 +
Paper and Pencil
 +
 
 +
 +
=== Process ===
 +
 +
Solve the problems A and B
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
A. 27 members of a
 +
class were given a puzzle to solve and the times (in minutes) each
 +
pupil took to solve it were noted.
 +
 
 +
 +
 
 +
 
 +
 
 +
       
 +
{| border="1"
 +
|-
 +
|
 +
'''the times (in minutes) each pupil took'''
 +
 
 +
 +
|-
 +
|
 +
19 14 15 9 18 16 10 11 16
 +
 
 +
 +
4 20 10 14 11 9 13 15 13
 +
 
 +
 +
12 2 17 15 14 10 11 10 12
 +
 
 +
 +
|}
 +
 
 +
 
 +
 
 +
 +
 
 +
 
 +
 
 +
 +
# The MEAN value of a set of data is Sum of Values / Number of Values . What is the mean (to 2 decimal places) of the times given in the table?
 +
# The MEDIAN is the middle value of an ordered set of data.
 +
## Write down the times in the table above in ascending order.
 +
## How many values are there?
 +
## What is the median ?
 +
#
 +
# The MODE is the value which occurs most often, i.e. the most popular.
 +
## What is the mode of the times in the table above?
 +
#
 +
# Which of the three measures do you think is most representative of the average time? In this case it is probably the mean, but this will not always be so.
 +
 +
 
 +
 
 +
 
 +
 +
'''B Choosing which measure to use '''
 +
 
 +
 +
The sales in one week of a particular dress are
 +
given in terms of the dress sizes.
 +
 
 +
 +
# Determine the mean, median and mode for this data .
 +
# What is the size that is sold the most ?
 +
# Which of these measures is of most use?
 +
 +
 
 +
 
 +
 
 +
 +
Dress sizes sold in one week
 +
 
 +
             
 +
{| border="1"
 +
|-
 +
|
 +
10
 +
 
 +
 +
16
 +
 
 +
 +
16
 +
 
 +
 +
12
 +
 
 +
 +
16
 +
 
 +
 +
|
 +
14
 +
 
 +
 +
12
 +
 
 +
 +
14
 +
 
 +
 +
16
 +
 
 +
 +
18
 +
 
 +
 +
|
 +
12
 +
 
 +
 +
10
 +
 
 +
 +
18
 +
 
 +
 +
10
 +
 
 +
 +
14
 +
 
 +
 +
|
 +
16
 +
 
 +
 +
14
 +
 
 +
 +
8
 +
 
 +
 +
10
 +
 
 +
 +
16
 +
 
 +
 +
|
 +
18
 +
 
 +
 +
16
 +
 
 +
 +
14
 +
 
 +
 +
16
 +
 
 +
 +
8
 +
 
 +
 +
|}
 +
 
 +
 
 +
 
 +
 +
=== Evaluation ===
 +
 +
# Does the student understand the difference between Mean, Median and Mode
 +
# Can the student calculate each of the measures ?
 +
# Does the student know which measure is useful and represents the actual data given a data set ?

Revision as of 14:05, 25 September 2012

Scope of this document

The following is a background literature for teachers. It summarises the things to be known to a teacher to teach this topic more effectively . This literature is meant to be a ready reference for the teacher to develop the concepts, inculcate necessary skills, and impart knowledge in Statistics from Class 6 to Class 10.


Syllabus

Class


Topic


6


Data handling


(i) What is data - choosing data to examine a hypothesis?


(ii) Collection and organisation of data examples of organising it in tally bars and a table.


(iii) Pictograph- Need for scaling in pictographs interpretation & construction.


7


Data handling


(i) Collection and organisation of data – choosing the data to collect for a hypothesis testing.


(ii) Mean, median and mode of ungrouped data understanding what they represent.


(iii) Constructing bar graphs


(iv) Feel of probability using data through experiments. Notion of chance in events like tossing coins, dice etc. Tabulating and counting occurrences of 1 through 6 in a number of throws. Preparing the bar graph. Comparing the observation with that for a coin. Observing strings of throws, notion of Randomness of ungrouped data.


9


Statistics


Mean, median, mode of grouped and un-grouped data, a review; range quartile deviation and mean diviation for a given grouped and un-grouped data; graphical representation;construction and interpretation of histograms of varying width, ogives and frequency polygons; review of random experiments leading to the concept of chance or probability.


10


Statistics


Standard deviation of grouped and un-grouped data; calculation of standard deviation by direct method; coefficient of variation; construction and interpretation of pie charts






Curricular Objectives

  1. To understand the meaning of data. The need for statistics and how to collect, organise and represent data in different ways.
  2. Skills to represent and analyse data in tabular and graphical forms.
  3. Understanding central tendency and computation of the measure of central tendency namely arthmetic mean, median and mode for both grouped and ungrouped data. Have the ability to use the appropriate central tendency depending on the data.
  4. Understanding dispersion determine the measures of dispersion such as range quartile deviation, mean deviation and standard deviation.
  5. Understand the limitations and drawbacks of statistics

Concept Map

Statistics html m14464871.jpg




Theme Plan


THEME PLAN FOR THE TOPIC STATISTICS




CLASS


SUBTOPIC


CONCEPT DEVELOPMENT


KNOWLEDGE


SKILL


ACTIVITY


6


Data reading, comprehension and data collection


Data is a collection of facts, such as values or measurements. It can be numbers, words, measurements, observations or even just descriptions of things.



The need for statistics – to be able to analyse and draw conclusions for a large set of data by organising data in different ways and observing patterns.


Data and patterns of data. Raw Scores Class Intervals, Tally Marks and usage. Frequency in statistcs.


Identification of patterns and different methods of collection of data and collation of data


ACTIVITY1


7


Graphical representation of Data


Tabular data can be also represented in the form of a picture ( charts) as visual representations can sometimes be easier to interpret.



There are different types of pictorial representations that can be used to represent different type of data.



Looking at the data be able to select the chart that would clearly represent the data as well as convey intended information about the data


Frequency Distribution, Class intervals, Bar Chart, Pie Chart , Histogram


Given statistical data in a table format, develop the skills to select the appropriate chart. Represent the data as a chart and be able to interpret data given a chart.


ACTIVITY 2


9


Central tendency


A measure of central tendency is a single value that attempts to describe a set of data by identifying the central position within that set of data.


The mean, median and mode are all valid measures of central tendency but, under different conditions, some measures of central tendency become more appropriate to use than others.


Mean, Median and Mode as methods of calculating central tendency


Calculation of mean and median Analyse data and make conclusions


ACTIVITY 3


9 & 10


Dispersion


A measure of dispersion is a measure of spread, is used to describe the variability in a sample or population.



It is usually used in conjunction with a measure of central tendency, such as, the mean or median, to provide an overall description of a set of data.



It important to measure the spread of data because we can understand its relationship with measures of central tendency to make more accurate interpretation of data.


Range, Quartile, Standard Deviation , Cumulative Frequency


Calculation of Co-efficient of Variation. Meaning and interpretation of C.V. Analyse data and make conclusions






Statistics

Statistics is the study of the collection, organization, and interpretation of data. It deals with all aspects of this, including the planning of data collection in terms of the design of surveys and experiments. (source [[1]])



Statistics is a set of tools used to organize and analyze data. Data must either be numeric in origin or transformed by researchers into numbers. For instance, statistics could be used to analyze percentage scores English students receive on a grammar test: the percentage scores ranging from 0 to 100 are already in numeric form. Statistics could also be used to analyze grades on an essay by assigning numeric values to the letter grades, e.g., A=4, B=3, C=2, D=1, and F=0. Though this is not strictly necessary, statistical computations can be done on a set of textual data as in this case, translating them into numeric data has been a convention in the past.




A statistician is someone who is particularly well versed in the ways of thinking necessary for the successful application of statistical analysis. Such people have often gained this experience through working in any of a wide number of fields. There is also a discipline called mathematical statistics, which is concerned with the theoretical basis of the subject.


The word statistics, when referring to the scientific discipline, is singular, as in "Statistics is an art."This should not be confused with the word statistic, referring to a quantity (such as mean or median) calculated from a set of data,whose plural is statistics ("this statistic seems wrong" or "these statistics are misleading"). Source - http://en.wikipedia.org/wiki/Statistics


Statistical is concerned with the planning of studies, especially with the design of randomized experiments and with the planning of surveys using random sampling.


Of course, the data from a randomized study can be analyzed to consider secondary hypotheses or to suggest new ideas. A secondary analysis of the data from a planned study uses tools from data analysis.


Data analysis is divided into:


  • descriptive statistics - the part of statistics that describes data, i.e. summarises the data and their typical properties.
  • inferential statistics - the part of statistics that draws conclusions from data (using some model for the data): For example, inferential statistics involves selecting a model for the data, checking whether the data fulfill the conditions of a particular model, and with quantifying the involved uncertainty (e.g. using confidence intervals).



While the tools of data analysis work best on data from randomized studies, they are also applied to other kinds of data --- for example, from natural experiments and observational studies, in which case the inference is dependent on the model chosen by the statistician, and so subjective.


Mathematical statistics has been inspired by and has extended many procedures in applied statistics.


Descriptive and Inferential Statistics

When analysing data, for example, the marks achieved by 100 students for a piece of coursework, it is possible to use both descriptive and inferential statistics in your analysis of their marks. Typically, in most research conducted on groups of people, you will use both descriptive and inferential statistics to analyse your results and draw conclusions. So what are descriptive and inferential statistics? And what are their differences?




Descriptive Statistics

Descriptive statistics is the term given to the analysis of data that helps describe, show or summarize data in a meaningful way such that, for example, patterns might emerge from the data. Descriptive statistics do not, however, allow us to make conclusions beyond the data we have analysed or reach conclusions regarding any hypotheses we might have made. They are simply a way to describe our data.




Descriptive statistics are very important, as if we simply presented our raw data it would be hard to visulize what the data was showing, especially if there was a lot of it. Descriptive statistics therefore allow us to present the data in a more meaningful way which allows simpler interpretation of the data. For example, if we had the results of 100 pieces of students' coursework, we may be interested in the overall performance of those students. We would also be interested in the distribution or spread of the marks. Descriptive statistics allow us to do this. How to properly describe data through statistics and graphs is an important topic and discussed in other Laerd Statistics Guides. Typically, there are two general types of statistic that are used to describe data:




Measures of central tendency: these are ways of describing the central position of a frequency distribution for a group of data. In this case, the frequency distribution is simply the distribution and pattern of marks scored by the 100 students from the lowest to the highest. We can describe this central position using a number of statistics, including the mode, median, and mean. You can read about measures of central tendency here.




Measures of spread: these are ways of summarizing a group of data by describing how spread out the scores are. For example, the mean score of our 100 students may be 65 out of 100. However, not all students will have scored 65 marks. Rather, their scores will be spread out. Some will be lower and others higher. Measures of spread help us to summarize how spread out these scores are. To describe this spread, a number of statistics are available to us, including the range, quartiles, absolute deviation, variance and standard deviation.




When we use descriptive statistics it is useful to summarize our group of data using a combination of tabulated description (i.e. tables), graphical description (i.e. graphs and charts) and statistical commentary (i.e. a discussion of the results).




Inferential Statistics

We have seen that descriptive statistics provide information about our immediate group of data. For example, we could calculate the mean and standard deviation of the exam marks for the 100 students and this could provide valuable information about this group of 100 students. Any group of data like this, that includes all the data you are interested, in is called a population. A population can be small or large, as long as it includes all the data you are interested in. For example, if you were only interested in the exam marks of 100 students, then the 100 students would represent your population. Descriptive statistics are applied to populations and the properties of populations, like the mean or standard deviation, are called parameters as they represent the whole population (i.e. everybody you are interested in).




Often, however, you do not have access to the whole population you are interested in investigating but only have a limited number of data instead. For example, you might be interested in the exam marks of all students in the UK. It is not feasible to measure all exam marks of all students in the whole of the UK so you have to measure a smaller sample of students, for example, 100 students, that are used to represent the larger population of all UK students. Properties of samples, such as the mean or standard deviation, are not called parameters but statistics. Inferential statistics are techniques that allow us to use these samples to make generalizations about the populations from which the samples were drawn. It is, therefore, important the sample accurately represents the population. The process of achieving this is called sampling (sampling strategies are discussed in detail here on our sister site). Inferential statistics arise out of the fact that sampling naturally incurs sampling error and thus a sample is not expected to perfectly represent the population. The methods of inferential statistics are (1) the estimation of parameter(s) and (2) testing of statistical hypotheses.


Data handling

The term data refers to qualitative or quantitative attributes of a variable or set of variables.Data refers to the pieces of information that have been observed and recorded, from an experiment or a survey. There are two types of data: primary and secondary. The word ”data” is the plural of the word ”datum”, and therefore one should say, ”the data are” and not ”the data is”. Data can be classified as primary or secondary, and primary or secondary data can be classified as qualitative or quantitative.


Figure 16.1 summarises the classifications of data. Primary data describes the original data that have been collected. This type of data is also known as raw data. Often the primary data set is very large and is therefore summarised or processed to extract meaningful information. Qualitative data is information that cannot be written as numbers, for example, if you were collecting data from people on how they feel or what their favourite colour is.Quantitative data is information that can be written as numbers, for example, if you were collecting data from people on their height or weight.


















Secondary data is primary data that has been summarised or processed, for example, the set


of colours that people gave as favourite colours would be secondary data because it is a


summary of responses. Data already collected prior our use is secondary data. Primary data is what we collect as a part of our study. All processed data therefore is also secondary.



Transforming primary data into secondary data through analysis, grouping or organisation into secondary data is the process of generating information.



Purpose of Collecting Primary Data

Data is collected to provide answers that help with understanding a particular situation. Here are examples to illustrate some real world data collections scenarios in the categories of qualitative and quantitative data.


Qualitative Data

• The local government might want to know how many residents have electricity and might


ask the question: ”Does your home have a safesupply of electricity?”


• A supermarket manager might ask the question: “What flavours of soft drink should be


stocked in my supermarket?” The question asked of customers might be “What is your


favourite soft drink?” Based on the customers’ responses, the manager can make an


informed decision as to what soft drinks to stock.


• A company manufacturing medicines might ask “How effective is our pill at relieving a


headache?” The question asked of people using the pill for a headache might be: “Does


taking the pill relieve your headache?” Based on responses, the company learns how


effective their product is.


• A motor car company might want to improve their customer service, and might ask their


customers: “How can we improve our customer service?”


A teacher may ask “How many hours of TV by students on TV' to get an idea of what children are learning from TV at home and how it supplements (or affects) the learning in the school



Quantitative Data

• A cell phone manufacturing company might collect data about how often people buy new


cell phones and what factors affect their choice, so that the cell phone company can focus


on those features that would make their product more attractive to buyers.


• A town councillor might want to know how many accidents have occurred at a particular


intersection, to decide whether a robot should be installed. The councillor would visit the


local police station to research their records to collect the appropriate data.


• A supermarket manager might ask the question: “What flavours of soft drink should be


stocked in my supermarket?” The question asked of customers might be “What is your


favourite soft drink?” Based on the customers’ responses, the manager can make an


informed decision as to what soft drinks to stock.


What kind of TV programs are watched by students, how many are educational in nature.






However, it is important to note that different questions reveal different features of a situation, and that this affects the ability to understand the situation. For example, if the question in the list What kind of TV programs are watched by students, how many are educational in nature. was re-phrased to be: Do your children watch educational programs on TV and if you answered yes, but most programs being watched were of entertainment value, , then this could give the wrong impression that TV was being used as an educational tool in your home .


Methods of Data Collection

The method of collecting the data must be appropriate to the question being asked. Some


examples of data collecting methods are:


  1. Experiments
  2. Questionnaires, surveys, focus group discussions and interviews
  3. Other sources (friends, family, newspapers, books, magazines and now increasingly the Internet)
  4. Observation
  5. Specialised equipment (rainwater guages to measure rainfall in a place, various medical equipment that collect information about different biological processes)



The most important aspect of each method of data collecting is to clearly formulate the question that is to be answered. The details of the data collection should therefore be structured to take your question into account.



You must have observed your teacher recording the attendance of students in your class everyday, or recording marks obtained by you after every test or examination. Similarly, you must have also seen a cricket score board. One score boards have been illustrated here :






NatWest One Day International Series: England v India Friday, 16 September 2011 at The Swalec Stadium


England beat India by 6 wickets (D/L). England won the toss and decided to field


India Innings


304 for 6 (50.0 overs)


England Innings


241 for 4 (32.2 overs)



India 1st Innings - Close


Runs


Balls


4s


6s


P Patel


c Bresnan


b Swann


19


39


0


0


Rahane


c Finn


b Dernbach


26


47


3


0


Dravid


b Swann


69


79


4


0


Kohli


hit wicket


b Swann


107


93


9


1


Raina


c Bresnan


b Finn


15


15


0


1


Dhoni


not out


50


26


5


2


Jadeja


c Bopara


b Dernbach


0


1


0


0


Ashwin


not out


0


0


0


0


Extras


6w 1b 11lb


18


Total


for 6


304


(50.0 ovs)



Bowler


Overs


Maidens


Runs


Wickets


Bresnan


9.0


0


62


0


Finn


10.0


1


44


1


Dernbach


10.0


0


73


2


Swann


9.0


0


34


3


S Patel


8.0


0


55


0


Bopara


4.0


0


24


0




Recording Data

Let us take an example of a class which is preparing to go for a picnic. The teacher asked the students to give their choice of fruits out of banana, apple, orange or guava. Uma is asked to prepare the list. She prepared a list of all the children and wrote the choice of fruit against each name. This list would help the teacher to distribute fruits according to the choice.




Raghav — Banana


Preeti — Apple


Amar — Guava


Fatima — Orange


Amita — Apple


Raman — Banana


Radha — Orange


Farida — Guava


Anuradha — Banana


Rati — Banana


Bhawana — Apple


Manoj — Banana


Donald — Apple


Maria — Banana


Uma — Orange


Akhtar — Guava


Ritu — Apple


Salma — Banana


Kavita — Guava


Javed — Banana






Example 1 : A teacher wants to know the choice of food of each student as part of the mid-day meal programme. The teacher assigns the task of collecting this information to Maria. Maria does so using a paper and a pencil. After arranging the choices in a column, she puts against a choice of food one ( | ) mark for every student making that choice.


Choice


Number of students


Rice only


Chapati only


Both rice and chapati







Umesh, after seeing the table suggested a better method to count the students. He asked Maria to organise the marks ( | ) in a group of ten as shown below :


Choice


Tally marks


Number of students


Rice only


Chapati only


Both rice and chapati





17


13


20



Rajan made it simpler by asking her to make groups of five instead of ten, as


shown below :


Choice


Tally marks


Number of students


Rice only


Chapati only


Both rice and chapati





17


13


20





Meaning of Frequency

Frequency means the number of occurrences within a given time period.


It is not easy to answer the question looking at the choices written haphazardly. We


arrange the data in Table 1 using tally marks.


Table 1


Subject


Tally Marks


Number of Students


Art



7


Mathematics



5


Science



6


English



4



The number of tallies before each subject gives the number of students who like that


particular subject. This is known as the frequency of that subject. Frequency gives the number of times that a particular entry occurs. From Table 1, Frequency of students who like English is 4 Frequency of students who like Mathematics is 5 The table made is known as frequency distribution table as it gives the number of times an entry occurs.



Categorical Frequency Distributions

Categorical frequency distributions - can be used for data that can be placed in specific categories, such as nominal- or ordinal-level data. (nominal or ordinal also called discrete data is where we can distinctly count the occurences of a variable).



Examples - political affiliation, religious affiliation, blood type etc.


Class


Frequency


Percent


A


5


20


B


7


28


C


9


36


D


4


16



Blood Type frequency distribution example


Graphical Representations

Histogram & Bar Chart

What is a histogram?

A histogram is a plot that lets you discover, and show, the underlying frequency distribution (shape) of a set of continuous data. This allows the inspection of the data for its underlying distribution (e.g. normal distribution), outliers, skewness, etc. An example of a histogram, and the raw data it was constructed from, is shown below:



Statistics html 6201ec25.png


























36 25 38 46 55 68 72 55 36 38


67 45 22 48 91 46 52 61 58 55


How do you construct a histogram from a continuous variable?

To construct a histogram from a continuous variable you first need to split the data into intervals, called bins. In the example above, age has been split into bins, with each bin representing a 10-year period starting at 20 years. Each bin contains the number of occurrences of scores in the data set that are contained within that bin. For the above data set, the frequencies in each bin have been tabulated along with the scores that contributed to the frequency in each bin (see below):



Bin Frequency Scores Included in Bin


20-30 2 25,22


30-40 4 36,38,36,38


40-50 4 46,45,48,46


50-60 5 55,55,52,58,55


60-70 3 68,67,61


70-80 1 72


80-90 0 -


90-100 1 91



Notice that, unlike a bar chart, there are no "gaps" between the bars (although some bars might be "absent" reflecting no frequencies). This is because a histogram represents a continuous data set, and as such, there are no gaps in the data. (Although you will have to decide whether you round up or round down scores on the boundaries of bins)



Choosing the correct bin width

There is no right or wrong answer as to how wide a bin should be, but there are rules of thumb. You need to make sure that the bins are not too small or too large. Consider the histogram we produced earlier (see above): the following histograms use the same data but have either much smaller or larger bins, as shown below:



Statistics html 75ab55c3.png





We can see from the histogram on the left, that the bin width is too small as it shows too much individual data and does not allow the underlying pattern (frequency distribution) of the data to be easily seen. At the other end of the scale, is the diagram on the right, where the bins are too large and, again, we are unable to find the underlying trend in the data.


Histograms are based on area not height of bars



In a histogram, it is the area of the bar that indicates the frequency of occurrences for each bin. This means that the height of the bar does not necessarily indicate how many occurrences of scores there were within each individual bin. It is the product of height multiplied by the width of the bin that indicates the frequency of occurrences within that bin. One of the reasons that the height of the bars is often incorrectly assessed as indicating frequency and not the area of the bar is due to the fact that a lot of histograms often have equally spaced bars (bins) and, under these circumstances, the height of the bin does reflect the frequency.



What is the difference between a bar chart and a histogram?

Statistics html 6dfca87b.png


The major difference is that a histogram is only used to plot the frequency of score occurrences in a continuous data set that has been divided into classes, called bins. Bar charts, on the other hand, can be used for a great deal of other types of variables including ordinal and nominal data sets.






Circle or Pie Chart

These are called circle graphs. A circle graph shows the relationship between a whole and its parts. Here, the whole circle is divided into sectors. The size of each sector is proportional to the activity or information it represents.



A variety of graphical representations of data are now possible using spreadsheet software. OpenOffice CALC can convert a table of data into bar charts, pie charts, area charts etc and make data much more easy to read/interpret.



Types of Variables

All experiments examine some kind of variable(s). A variable is not only something that we measure, but also something that we can manipulate and something we can control for. To understand the characteristics of variables and how we use them in research, this guide is divided into three main sections. First, we illustrate the role of dependent and independent variables. Second, we discuss the difference between experimental and non-experimental research. Finally, we explain how variables can be characterised as either categorical or continuous.


Dependent and Independent Variables

An independent variable, sometimes called an experimental or predictor variable, is a variable that is being manipulated in an experiment in order to observe the effect on a dependent variable, sometimes called an outcome variable.




Imagine that a tutor asks 100 students to complete a maths test. The tutor wants to know why some students perform better than others. Whilst the tutor does not know the answer to this, she thinks that it might be because of two reasons: (1) some students spend more time revising for their test; and (2) some students are naturally more intelligent than others. As such, the tutor decides to investigate the effect of revision time and intelligence on the test performance of the 100 students. The dependent and independent variables for the study are:




Dependent Variable: Test Mark (measured from 0 to 100)




Independent Variables: Revision time (measured in hours) Intelligence (measured using IQ score)




The dependent variable is simply that, a variable that is dependent on an independent variable(s). For example, in our case the test mark that a student achieves is dependent on revision time and intelligence. Whilst revision time and intelligence (the independent variables) may (or may not) cause a change in the test mark (the dependent variable), the reverse is implausible; in other words, whilst the number of hours a student spends revising and the higher a student's IQ score may (or may not) change the test mark that a student achieves, a change in a student's test mark has no bearing on whether a student revises more or is more intelligent (this simply doesn't make sense).




Therefore, the aim of the tutor's investigation is to examine whether these independent variables - revision time and IQ - result in a change in the dependent variable, the students' test scores. However, it is also worth noting that whilst this is the main aim of the experiment, the tutor may also be interested to know if the independent variables - revision time and IQ - are also connected in some way.




In the section on experimental and non-experimental research that follows, we find out a little more about the nature of independent and dependent variables.




Experimental and Non-Experimental Research

Experimental research: In experimental research, the aim is to manipulate an independent variable(s) and then examine the effect that this change has on a dependent variable(s). Since it is possible to manipulate the independent variable(s), experimental research has the advantage of enabling a researcher to identify a cause and effect between variables. For example, take our example of 100 students completing a maths exam where the dependent variable was the exam mark (measured from 0 to 100) and the independent variables were revision time (measured in hours) and intelligence (measured using IQ score). Here, it would be possible to use an experimental design and manipulate the revision time of the students. The tutor could divide the students into two groups, each made up of 50 students. In "group one", the tutor could ask the students not to do any revision. Alternately, "group two" could be asked to do 20 hours of revision in the two weeks prior to the test. The tutor could then compare the marks that the students achieved.


Non-experimental research: In non-experimental research, the researcher does not manipulate the independent variable(s). This is not to say that it is impossible to do so, but it will either be impractical or unethical to do so. For example, a researcher may be interested in the effect of illegal, recreational drug use (the dependent variable(s)) on certain types of behaviour (the independent variable(s)). However, whilst possible, it would be unethical to ask individuals to take illegal drugs in order to study what effect this had on certain behaviours. As such, a researcher could ask both drug and non-drug users to complete a questionnaire that had been constructed to indicate the extent to which they exhibited certain behaviours. Whilst it is not possible to identify the cause and effect between the variables, we can still examine the association or relationship between them.In addition to understanding the difference between dependent and independent variables, and experimental and non-experimental research, it is also important to understand the different characteristics amongst variables. This is discussed next.




Categorical and Continuous Variables

Categorical variables are also known as discrete or qualitative variables. Categorical variables can be further categorized as either nominal, ordinal or dichotomous.




Nominal variables are variables that have two or more categories but which do not have an intrinsic order. For example, a real estate agent could classify their types of property into distinct categories such as houses, condos, co-ops or bungalows. So "type of property" is a nominal variable with 4 categories called houses, condos, co-ops and bungalows. Of note, the different categories of a nominal variable can also be referred to as groups or levels of the nominal variable. Another example of a nominal variable would be classifying where people live in USA by state. In this case there will be many more levels of the nominal variable (50 in fact).


Dichotomous variables are nominal variables which have only two categories or levels. For example, if we were looking at gender, we would most probably categorize somebody as either "male" or "female". This is an example of a dichotomous variable (and also a nominal variable). Another example might be if we asked a person if they owned a mobile phone. Here, we may categorise mobile phone ownership as either "Yes" or "No". In the real estate agent example, if type of property had been classified as either residential or commercial then "type of property" would be a dichotomous variable.


Ordinal variables are variables that have two or more categories just like nominal variables only the categories can also be ordered or ranked. So if you asked someone if they liked the policies of the Democratic Party and they could answer either "Not very much", "They are OK" or "Yes, a lot" then you have an ordinal variable. Why? Because you have 3 categories, namely "Not very much", "They are OK" and "Yes, a lot" and you can rank them from the most positive (Yes, a lot), to the middle response (They are OK), to the least positive (Not very much). However, whilst we can rank the levels, we cannot place a "value" to them; we cannot say that "They are OK" is twice as positive as "Not very much" for example.




Continuous variables are also known as quantitative variables. Continuous variables can be further categorized as either interval or ratio variables.




Interval variables are variables for which their central characteristic is that they can be measured along a continuum and they have a numerical value (for example, temperature measured in degrees Celsius or Fahrenheit). So the difference between 20C and 30C is the same as 30C to 40C. However, temperature measured in degrees Celsius or Fahrenheit is NOT a ratio variable.


Ratio variables are interval variables but with the added condition that 0 (zero) of the measurement indicates that there is none of that variable. So, temperature measured in degrees Celsius or Fahrenheit is not a ratio variable because 0C does not mean there is no temperature. However, temperature measured in Kelvin is a ratio variable as 0 Kelvin (often called absolute zero) indicates that there is no temperature whatsoever. Other examples of ratio variables include height, mass, distance and many more. The name "ratio" reflects the fact that you can use the ratio of measurements. So, for example, a distance of ten metres is twice the distance of 5 metres.




Ambiguities in classifying a type of variable

In some cases, the measurement scale for data is ordinal but the variable is treated as continuous. For example, a Likert scale that contains five values - strongly agree, agree, neither agree nor disagree, disagree, and strongly disagree - is ordinal. However, where a Likert scale contains seven or more value - strongly agree, moderately agree, agree, neither agree nor disagree, disagree, moderately disagree, and strongly disagree - the underlying scale is sometimes treated as continuous although where you should do this is a cause of great dispute.




It is worth noting that how we categorise variables is somewhat of a choice. Whilst we categorised gender as a dichotomous variable (you are either male or female), social scientists may disagree with this, arguing that gender is a more complex variable involving more than two distinctions, but also including measurement levels like genderqueer, intersex, and transgender. At the same time, some researchers would argue that a Likert scale, even with seven values, should never be treated as a continuous variable.


Central Tendency

Introduction

A measure of central tendency is a single value that attempts to describe a set of data by identifying the central position within that set of data. As such, measures of central tendency are sometimes called measures of central location. They are also classed as summary statistics. The mean (often called the average) is most likely the measure of central tendency that you are most familiar with, but there are others, such as, the median and the mode.


The mean, median and mode are all valid measures of central tendency but, under different conditions, some measures of central tendency become more appropriate to use than others. In the following sections we will look at the mean, mode and median and learn how to calculate them and under what conditions they are most appropriate to be used.


Mean (Arithmetic)

The mean (or average) is the most popular and well known measure of central tendency. It can be used with both discrete and continuous data, although its use is most often with continuous data. The mean is equal to the sum of all the values in the data set divided by the number of values in the data set. So, if we have n values in a data set and they have values x1, x2, ..., xn, then the sample mean, usually denoted by Statistics html 174cec39.gif (pronounced x bar), is:




Statistics html 69b2cf9e.gif


This formula is usually written in a slightly different manner using the Greek capitol letter, Σ, pronounced "sigma", which means "sum of...":


Statistics html m50e9a786.gif


You may have noticed that the above formula refers to the sample mean. So, why call have we called it a sample mean? This is because, in statistics, samples and populations have very different meanings and these differences are very important, even if, in the case of the mean, they are calculated in the same way. To acknowledge that we are calculating the population mean and not the sample mean, we use the Greek lower case letter "mu", denoted as µ:


Statistics html 7b1e9596.gif


The mean is essentially a model of your data set. It is the value that is most common. You will notice, however, that the mean is not often one of the actual values that you have observed in your data set. However, one of its important properties is that it minimises error in the prediction of any one value in your data set. That is, it is the value that produces the lowest amount of error from all other values in the data set.


An important property of the mean is that it includes every value in your data set as part of the calculation. In addition, the mean is the only measure of central tendency where the sum of the deviations of each value from the mean is always zero.




When not to use the mean


The mean has one main disadvantage: it is particularly susceptible to the influence of outliers. These are values that are unusual compared to the rest of the data set by being especially small or large in numerical value. For example, consider the wages of staff at a factory below:


Staff


1


2


3


4


5


6


7


8


9


10


Salary


15k


18k


16k


14k


15k


15k


12k


17k


90k


95k


The mean salary for these ten staff is $30.7k. However, inspecting the raw data suggests that this mean value might not be the best way to accurately reflect the typical salary of a worker, as most workers have salaries in the $12k to 18k range. The mean is being skewed by the two large salaries. Therefore, in this situation we would like to have a better measure of central tendency. As we will find out later, taking the median would be a better measure of central tendency in this situation.


Another time when we usually prefer the median over the mean (or mode) is when our data is skewed (i.e. the frequency distribution for our data is skewed). If we consider the normal distribution - as this is the most frequently assessed in statistics - when the data is perfectly normal then the mean, median and mode are identical. Moreover, they all represent the most typical value in the data set. However, as the data becomes skewed the mean loses its ability to provide the best central location for the data as the skewed data is dragging it away from the typical value. However, the median best retains this position and is not as strongly influenced by the skewed values. This is explained in more detail in the skewed distribution section later in this guide.


Median

The median is the middle score for a set of data that has been arranged in order of magnitude. The median is less affected by outliers and skewed data. In order to calculate the median, suppose we have the data below:




65


55


89


56


35


14


56


55


87


45


92




We first need to rearrange that data into order of magnitude (smallest first):




14


35


45


55


55


56


56


65


87


89


92




Our median mark is the middle mark - in this case 56 (highlighted in bold). It is the middle mark because there are 5 scores before it and 5 scores after it. This works fine when you have an odd number of scores but what happens when you have an even number of scores? What if you had only 10 scores? Well, you simply have to take the middle two scores and average the result. So, if we look at the example below:




65


55


89


56


35


14


56


55


87


45




We again rearrange that data into order of magnitude (smallest first):



14


35


45


55


55


56


56


65


87


89


92




Only now we have to take the 5th and 6th score in our data set and average them to get a median of 55.5.


Mode

The mode is the most frequent score in our data set. On a histogram it represents the highest bar in a bar chart or histogram. You can, therefore, sometimes consider the mode as being the most popular option. An example of a mode is presented below:




Normally, the mode is used for categorical data where we wish to know which is the most common category as illustrated below:


We can see above that the most common form of transport, in this particular data set, is the bus. However, one of the problems with the mode is that it is not unique, so it leaves us with problems when we have two or more values that share the highest frequency, such as below:






















We are now stuck as to which mode best describes the central tendency of the data. This is particularly problematic when we have continuous data, as we are more likely not to have any one value that is more frequent than the other. For example, consider measuring 30 peoples' weight (to the nearest 0.1 kg). How likely is it that we will find two or more people with exactly the same weight, e.g. 67.4 kg? The answer, is probably very unlikely - many people might be close but with such a small sample (30 people) and a large range of possible weights you are unlikely to find two people with exactly the same weight, that is, to the nearest 0.1 kg. This is why the mode is very rarely used with continuous data.




Another problem with the mode is that it will not provide us with a very good measure of central tendency when the most common mark is far away from the rest of the data in the data set, as depicted in the diagram below:










































In the above diagram the mode has a value of 2. We can clearly see, however, that the mode is not representative of the data, which is mostly concentrated around the 20 to 30 value range. To use the mode to describe the central tendency of this data set would be misleading.


Skewed Distributions and the Mean and Median

We often test whether our data is normally distributed as this is a common assumption underlying many statistical tests. An example of a normally distributed set of data is presented below:




When you have a normally distributed sample you can legitimately use both the mean or the median as your measure of central tendency. In fact, in any symmetrical distribution the mean, median and mode are equal. However, in this situation, the mean is widely preferred as the best measure of central tendency as it is the measure that includes all the values in the data set for its calculation, and any change in any of the scores will affect the value of the mean. This is not the case with the median or mode.


However, when our data is skewed, for example, as with the right-skewed data set below:












































we find that the mean is being dragged in the direct of the skew. In these situations, the median is generally considered to be the best representative of the central location of the data. The more skewed the distribution the greater the difference between the median and mean, and the greater emphasis should be placed on using the median as opposed to the mean. A classic example of the above right-skewed distribution is income (salary), where higher-earners provide a false representation of the typical income if expressed as a mean and not a median.


If dealing with a normal distribution, and tests of normality show that the data is non-normal, then it is customary to use the median instead of the mean. This is more a rule of thumb than a strict guideline however. Sometimes, researchers wish to report the mean of a skewed distribution if the median and mean are not appreciably different (a subjective assessment) and if it allows easier comparisons to previous research to be made.




Summary of when to use the mean, median and mode

Please use the following summary table to know what the best measure of central tendency is with respect to the different types of variables.




Type of Variable


Best measure of central tendency


Nominal


Mode


Ordinal


Median


Interval/Ratio (not skewed)


Mean


Interval/Ratio (skewed)


Median




Relative advantages and disadvantages of mean, median and mode

Mean. Advantages: Finds the most accurate average of the set of numbers. Disadvantages: Outliers (few values are very different from most) can change the mean a lot... making it much lower/higher than it should be.

Median: Advantages: Finds the middle number of a set of data, so outliers have little or no effect. Disadvantages: If the gap between some numbers is large, while it is small between other numbers in the data, this can cause the median to be a very inaccurate way to find the middle of a set of values.

Mode: Advantages: Allows you to see what value happened the most in a set of data. This can help you to figure out things in a different way. It is also quick and easy. Disadvantages: Could be very far from the actual middle of the data. The least reliable way to find the middle or average of the data.



This means that each of these measures can be useful in different kinds of distributions.



Dispersion

A measure of spread, sometimes also called a measure of dispersion, is used to describe the variability in a sample or population. It is usually used in conjunction with a measure of central tendency, such as, the mean or median, to provide an overall description of a set of data.




Why is it important to measure the spread of data?

There are many reasons why the measure of the spread of data values is important but one of the main reasons regards its relationship with measures of central tendency. A measure of spread gives us an idea of how well the mean, for example, represents the data. If the spread of values in the data set is large then the mean is not as representative of the data as if the spread of data is small. This is because a large spread indicates that there are probably large differences between individual scores. Additionally, in research, it is often seen as positive if there is little variation in each data group as it indicates that the similar.




We will be looking at the range, quartiles, variance, absolute deviation and standard deviation.




Range

The range is the difference between the highest and lowest scores in a data set and is the simplest measure of spread. So we calculate range as:




Range = maximum value - minimum value




For example, let us consider the following data set:


23 56 45 65 59 55 62 54 85 25




The maximum value is 85 and the minimum value is 23. This results in a range of 62, which is 85 minus 23. Whilst using the range as a measure of spread is limited, it does set the boundaries of the scores. This can be useful if you are measuring a variable that has either a critical low or high threshold (or both) that should not be crossed. The range will instantly inform you whether at least one value broke these critical thresholds. In addition, the range can be used to detect any errors when entering data. For example, if you have recorded the age of school children in your study and your range is 7 to 123 years old you know you have made a mistake!



Quartiles and Interquartile Range

Quartiles tell us about the spread of a data set by breaking the data set into quarters, just like the median breaks it in half. For example, consider the marks of the 100 students below, which have been ordered from the lowest to the highest scores, and the quartiles highlighted in red.




Order Score Order Score Order Score Order Score Order Score


1st 35 21st 42 41st 53 61st 64 81st 74


2nd 37 22nd 42 42nd 53 62nd 64 82nd 74


3rd 37 23rd 44 43rd 54 63rd 65 83rd 74


4th 38 24th 44 44th 55 64th 66 84th 75


5th 39 25th 45 45th 55 65th 67 85th 75


6th 39 26th 45 46th 56 66th 67 86th 76


7th 39 27th 45 47th 57 67th 67 87th 77


8th 39 28th 45 48th 57 68th 67 88th 77


9th 39 29th 47 49th 58 69th 68 89th 79


10th 40 30th 48 50th 58 70th 69 90th 80


11th 40 31st 49 51st 59 71st 69 91st 81


12th 40 32nd 49 52nd 60 72nd 69 92nd 81


13th 40 33rd 49 53rd 61 73rd 70 93rd 81


14th 40 34th 49 54th 62 74th 70 94th 81


15th 40 35th 51 55th 62 75th 71 95th 81


16th 41 36th 51 56th 62 76th 71 96th 81


17th 41 37th 51 57th 63 77th 71 97th 83


18th 42 38th 51 58th 63 78th 72 98th 84


19th 42 39th 52 59th 64 79th 74 99th 84


20th 42 40th 52 60th 64 80th 74 100th 85






The first quartile (Q1) lies between the 25th and 26th student's marks, the second quartile (Q2) between the 50th and 51st student's marks, and the third quartile (Q3) between the 75th and 76th student's marks. Hence:




First quartile (Q1) = 45 + 45 ÷ 2 = 45


Second quartile (Q2) = 58 + 59 ÷ 2 = 58.5


Third quartile (Q3) = 71 + 71 ÷ 2 = 71




In the above example, we have an even number of scores (100 students rather than an odd number such as 99 students). This means that when we calculate the quartiles, we take the sum of the two scores around each quartile and then half them (hence Q1= 45 + 45 ÷ 2 = 45) . However, if we had an odd number of scores (say, 99 students), then we would only need to take one score for each quartile (that is, the 25th, 50th and 75th scores). You should recognize that the second quartile is also the median.




Quartiles are a useful measure of spread because they are much less affected by outliers or a skewed data set than the equivalent measures of mean and standard deviation. For this reason, quartiles are often reported along with the median as the best choice of measure of spread and central tendency, respectively, when dealing with skewed and/or data with outliers. A common way of expressing quartiles is as an interquartile range. The interquartile range describes the difference between the third quartile (Q3) and the first quartile (Q1), telling us about the range of the middle half of the scores in the distribution. Hence, for our 100 students:




Interquartile range = Q3 - Q1


= 71 - 45


= 26




However, it should be noted that in journals and other publications you will usually see the interquartile range reported as 45 to 71, rather than the calculated range.




A slight variation on this is the semi-interquartile range, which is half the interquartile range = ½ (Q3 - Q1). Hence, for our 100 students, this would be 26 ÷ 2 = 13.


Standard Deviation

Introduction

The standard deviation is a measure of the spread of scores within a set of data. Usually, we are interested in the standard deviation of a population. However, as we are often presented with data from a sample only, we can estimate the population standard deviation from a sample standard deviation. These two standard deviations, sample and population standard deviations, are calculated differently. In statistics we are usually presented with having to calculate sample standard deviations, and so this is what this article will focus on, although the formula for a population standard deviation will also be shown.


When to use the sample or population standard deviation

We are normally interested in knowing the population standard deviation as our population contains all the values we are interested in. Therefore, you would normally calculate the population standard deviation if: (1) you have the entire population or (2) you have a sample of a larger population but you are only interested in this sample and do not wish to generalize your findings to the population. However, in statistics, we are usually presented with a sample from which we wish to estimate (generalize to) a population, and the standard deviation is no exception to this. Therefore, if all you have is a sample but you wish to make a statement about the population standard deviation from which the sample is drawn, then you need to use the sample standard deviation. Confusion can often arise as to which standard deviation to use due to the name "sample" standard deviation incorrectly being interpreted as meaning the standard deviation of the sample itself and not as the estimate of the population standard deviation based on the sample.


What type of data should you use when you calculate a standard deviation?

The standard deviation is used in conjunction with the mean, to summarise continuous data not categorical data. In addition, the standard deviation, like the mean, is normally only appropriate when the continuous data is not significantly skewed or has outliers.


Examples of when to use the sample or population standard deviation

Q. A teacher sets an exam for their pupils. The teacher wants to summarize the results the pupils attained as a mean and standard deviation. Which standard deviation should be used?


A. Population standard deviation. Why? Because the teacher is only interested in this class of pupils' scores and nobody else.


Q. A researcher has recruited males aged 45 to 65 years old for an exercise training study to investigate risk markers for heart disease, e.g. cholesterol. Which standard deviation would most likely be used?


A. Sample standard deviation. Although not explicitly stated, a researcher investigating health related issues will not be simply concerned with just the participants of their study; they will want to show how their sample results can be generalised to the whole population (in this case, males aged 45 to 65 years old). Hence, the use of the sample standard deviation.


Q. One of the questions on a national consensus survey asks for respondent's age. Which standard deviation would be used to describe the variation in all ages received from the consensus?


A. Population standard deviation. A national consensus is used to find out information about the nation's citizens. By definition, it includes the whole population, therefore, a population standard deviation would be used.


What are the formulas for the standard deviation?

The sample standard deviation formula is:


Statistics html m5610ded5.gif


where,


s = sample standard deviation Σ = sum of... X = sample mean n = number of scores in sample.


The population standard deviation formula is:


Statistics html m48922b88.gif


where,


σ = population standard deviation Σ = sum of... μ = population mean n = number of scores in sample.


Variation

Quartiles are useful but they are also somewhat limited because they do not take into account every score in our group of data. To get a more representative idea of spread we need to take into account the actual values of each score in a data set. The absolute deviation, variance and standard deviation are such measures.




The absolute and mean absolute deviation show the amount of deviation (variation) that occurs around the mean score. To find the total variability in our group of data, we simply add up the deviation of each score from the mean. The average deviation of a score can then be calculated by dividing this total by the number of scores. How we calculate the deviation of a score from the mean depends on our choice of statistic, whether we use absolute deviation, variance or standard deviation.




Absolute Deviation and Mean Absolute Deviation

Perhaps the simplest way of calculating the deviation of a score from the mean is to take each score and minus the mean score. For example, the mean score for the group of 100 students we used earlier was 58.75 out of 100. Therefore, if we took a student that scored 60 out of 100, the deviation of a score from the mean is 60 - 58.75 = 1.25. It is important to note that scores above the mean have positive deviations (as demonstrated above) whilst that scores below the mean will have negative deviations.




To find out the total variability in our data set, we would perform this calculation for all of the 100 students' scores. However, the problem is that because we have both positive and minus signs, when we add up all of these deviations, they cancel each other out, giving us a total deviation of zero. Since we are only interested in the deviations of the scores and not whether they are above or below the mean score, we can ignore the minus sign and take only the absolute value, giving us the absolute deviation. Adding up all of these absolute deviations and dividing them by the total number of scores then gives us the mean absolute deviation (see below). Therefore, for our 100 students the mean absolute deviation is 12.81, as shown below:




Variance

Another method for calculating the deviation of a group of scores from the mean, such as the 100 students we used earlier, is to use the variance. Unlike the absolute deviation, which uses the absolute value of the deviation in order to "rid itself" of the negative values, the variance achieves positive values by squaring each of the deviations instead. Adding up these squared deviations gives us the sum of squares, which we can then divide by the total number of scores in our group of data (in other words, 100 because there are 100 students) to find the variance (see below). Therefore, for our 100 students, the variance is 211.89, as shown below:




As a measure of variability, the variance is useful. If the scores in our group of data are spread out then the variance will be a large number. Conversely, if the scores are spread closely around the mean, then the variance will be a smaller number. However, there are two potential problems with the variance. First, because the deviations of scores from the mean are 'squared', this gives more weight to extreme scores. If our data contains outliers (in other words, one or a small number of scores that are particularly far away from the mean and perhaps do not represent well our data as a whole) this can give undo weight to these scores. Secondly, the variance is not in the same units as the scores in our data set: variance is measured in the units squared. This means we cannot place it on our frequency distribution and cannot directly relate its value to the values in our data set. Therefore, the figure of 211.89, our variance, appears somewhat arbitrary. Calculating the standard deviation rather than the variance rectifies this problem. Nonetheless, analysing variance is extremely important in some statistical analyses, discussed in other statistical guides.



Coefficient of variation

Coefficient of variation is defined as


Statistics html 1afc44b3.png





where v is the standard deviation and x is the mean of the given data. It is also called as


a relative standard deviation.


Remarks


(i) The coefficient of variation helps us to compare the consistency of two or more


collections of data.


(ii) When the coefficient of variation is more, the given data is less consistent.


(iii) When the coefficient of variation is less, the given data is more consistent.



Key Vocabulary

Additional Resources:

[[2]]


[[3]]




Activities :

Activity 1 : Data Collection

Objective

Understand collection of data and preparing frequency distrubution table for a given sets of sources


Procedure

Collect information regarding the number of family members of your classmates and represent it in the form of a table. Find to which category most students belong.






Number of family members


Tally marks members


Number of students


with that many


family members






Make a table and enter the data using tally marks. Find the number that appeared



(a) the minimum number of times?



(b) the maximum number of times?



(c) same number of times?





Avtivity 2: Histogram and Bar Chart

Objective

Learn to draw a histogram and bar chart. Understand the difference between a bar chart and a hsitogram and be able to select the approriate chart by looking at the problem and data.




Materials

Paper and Pencil


Procedure

Solve the problems A and B




In the past year, you have recorded the number of tickets that a movie theater has sold during each month. To represent this data set graphically, would you construct a bar graph or a histogram? Why is this choice better than the other? Using the following data, construct the graph that you choose.


Month


Number of Tickets Sold


January


25


February


20


March


15


April


20


May


30


June


35


July


40


August


20


September


25


October


15


November


20


December


30





B For a recent science project, you collected data regarding the distribution of fish and aquatic life in a nearby pond. Your data consists of the number of living creatures found in each 1 meter depth increment in the pond. Construct a bar graph and several histograms (vary the depth increment size) for the following data. In which case(s) is the histogram the same as the bar graph? How do the other histograms vary from the bar graph?



Depth Range


Number of Living Creatures


0 – 1 meters


10


1 – 2 meters


93


2 – 3 meters


23


3 – 4 meters


47


4 – 5 meters


68


5 – 6 meters


51


6 – 7 meters


43


7 – 8 meters


21


8 – 9 meters


15


9 – 10 meters


8


Evaluation

  1. Does the student understand the difference between a bar chart and a histogram ?
  2. Does the student know when to use each of these charts - - depending on the type of data continous and discrete ?

Activity 3 : Central Tendency

Objective

Learn to calculate each average measure - Mean, Median, Mode. And understand the difference between them. Know in which situation which measure must be used.




Materials

Paper and Pencil


Process

Solve the problems A and B




A. 27 members of a class were given a puzzle to solve and the times (in minutes) each pupil took to solve it were noted.




the times (in minutes) each pupil took


19 14 15 9 18 16 10 11 16


4 20 10 14 11 9 13 15 13


12 2 17 15 14 10 11 10 12






  1. The MEAN value of a set of data is Sum of Values / Number of Values . What is the mean (to 2 decimal places) of the times given in the table?
  2. The MEDIAN is the middle value of an ordered set of data.
    1. Write down the times in the table above in ascending order.
    2. How many values are there?
    3. What is the median ?
  3. The MODE is the value which occurs most often, i.e. the most popular.
    1. What is the mode of the times in the table above?
  4. Which of the three measures do you think is most representative of the average time? In this case it is probably the mean, but this will not always be so.



B Choosing which measure to use


The sales in one week of a particular dress are given in terms of the dress sizes.


  1. Determine the mean, median and mode for this data .
  2. What is the size that is sold the most ?
  3. Which of these measures is of most use?



Dress sizes sold in one week


10


16


16


12


16


14


12


14


16


18


12


10


18


10


14


16


14


8


10


16


18


16


14


16


8




Evaluation

  1. Does the student understand the difference between Mean, Median and Mode
  2. Can the student calculate each of the measures ?
  3. Does the student know which measure is useful and represents the actual data given a data set ?